Basic Mathematics: A Text Workbook

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Basic Mathematics: A Text Workbook

Basic Mathematics SEVENTH EDITION Charles P. McKeague CUESTA COLLEGE Australia • Brazil • Japan • Korea • Mexico • Sin

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Basic Mathematics SEVENTH EDITION

Charles P. McKeague CUESTA COLLEGE

Australia • Brazil • Japan • Korea • Mexico • Singapore • Spain • United Kingdom • United States

Basic Mathematics, Seventh Edition Charles P. McKeague Mathematics Editor: Marc Bove Publisher: Charlie Van Wagner Consulting Editor: Richard T. Jones Assistant Editor: Shaun Williams Editorial Assistant: Mary De La Cruz Media Editor: Maureen Ross Marketing Manager: Joe Rogove Marketing Assistant: Angela Kim Marketing Communications Manager: Katy Malatesta Project Manager, Editorial Production: Hal Humphrey Art Director: Vernon Boes Print Buyer: Judy Inouye

© 2010, 2005 Brooks/Cole, Cengage Learning ALL RIGHTS RESERVED. No part of this work covered by the copyright herein may be reproduced, transmitted, stored or used in any form or by any means graphic, electronic, or mechanical, including but not limited to photocopying, recording, scanning, digitizing, taping, Web distribution, information networks, or information storage and retrieval systems, except as permitted under Section 107 or 108 of the 1976 United States Copyright Act, without the prior written permission of the publisher. For product information and technology assistance, contact us at Cengage Learning Customer & Sales Support, 1-800-354-9706 For permission to use material from this text or product, submit all requests online at www.cengage.com/permissions Further permissions questions can be emailed to [email protected]

ISBN-13: 978-0-495-55974-0 ISBN-10: 0-495-55974-1

Permissions Editor: Bob Kauser Production Service: XYZ Textbooks Text Designer: Diane Beasley Photo Researcher: Kathleen Olson

Brooks/Cole 10 Davis Drive Belmont, CA 94002-3098 USA

Cover Designer: Irene Morris Cover Image: Pete McArthur Compositor: Devin Christ/XYZ Textbooks Illustrator: Kristina Chung/XYZ Textbooks

Cengage Learning is a leading provider of customized learning solutions with office locations around the globe, including Singapore, the United Kingdom, Australia, Mexico, Brazil, and Japan. Locate your local office at: www.cengage.com/international Cengage Learning products are represented in Canada by Nelson Education, Ltd. For your course and learning solutions, visit www.academic.cengage.com To learn more about Brooks/Cole, visit www.cengage.com/brookscole Purchase any of our products at your local college store or at our preferred online store www.ichapters.com

Printed in the United States of America 1 2 3 4 5 6 7 11 10 09 08

Brief Contents

Chapter

1

Whole Numbers

Chapter

2

Fractions and Mixed Numbers

Chapter

3

Decimals

Chapter

4

Ratio and Proportion

Chapter

5

Percent

Chapter

6

Measurement

Chapter

7

Introduction to Algebra

Chapter

8

Solving Equations

1 105

203 277

331 405 457

519

Appendix A

Resources

587

Appendix B

One Hundred Addition Facts

Appendix C

One Hundred Multiplication Facts

588 589

Solutions to Selected Practice Problems Answers to Odd-Numbered Problems Index

S-1 A-1

I-1

iii

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Contents

1

Whole Numbers

1

Introduction 1 1.1 Place Value and Names for Numbers

3

1.2 Addition with Whole Numbers, and Perimeter

13

1.3 Rounding Numbers, Estimating Answers, and Displaying Information 1.4 Subtraction with Whole Numbers 1.5 Multiplication with Whole Numbers 1.6 Division with Whole Numbers

33 41

55

1.7 Exponents, Order of Operations, and Averages 1.8 Area and Volume

25

67

81

Summary 91 Review 93 Test 97 Projects 99 A Glimpse of Algebra 101

2

Fractions and Mixed Numbers

105

Introduction 105 2.1 The Meaning and Properties of Fractions

107

2.2 Prime Numbers, Factors, and Reducing to Lowest Terms

119

2.3 Multiplication with Fractions, and the Area of a Triangle

127

2.4 Division with Fractions

139

2.5 Addition and Subtraction with Fractions 2.6 Mixed-Number Notation

147

159

2.7 Multiplication and Division with Mixed Numbers 2.8 Addition and Subtraction with Mixed Numbers

165 171

2.9 Combinations of Operations and Complex Fractions

179

Summary 187 Review 191 Cumulative Review 193 Test 195 Projects 197 A Glimpse of Algebra 199

v

vi

Contents

3

Decimals

203

Introduction 203 3.1 Decimal Notation and Place Value

205

3.2 Addition and Subtraction with Decimals

213

3.3 Multiplication with Decimals, Circumference and Area of a Circle 3.4 Division with Decimals

233

3.5 Fractions and Decimals, and the Volume of a Sphere 3.6 Square Roots and the Pythagorean Theorem

257

Summary 265 Review

267

Cumulative Review 268 Test

270

Projects 271 A Glimpse of Algebra 273

4

Ratio and Proportion Introduction 277 4.1 Ratios

279

4.2 Rates and Unit Pricing

287

4.3 Solving Equations by Division 4.4 Proportions

297

4.5 Applications of Proportions 4.6 Similar Figures

309

Summary 317 Review

319

Cumulative Review 321 Test

293

323

Projects 325 A Glimpse of Algebra 327

303

277

245

221

Contents

5

Percent

331

Introduction 331 5.1 Percents, Decimals, and Fractions 5.2 Basic Percent Problems

333

343

5.3 General Applications of Percent 353 5.4 Sales Tax and Commission

359

5.5 Percent Increase or Decrease and Discount 5.6 Interest

367

375

5.7 Pie Charts

383

Summary 391 Review 393 Cumulative Review 395 Test 397 Projects 399 A Glimpse of Algebra 401

6

Measurement

405

Introduction 405 6.1 Unit Analysis I: Length

407

6.2 Unit Analysis II: Area and Volume 417 6.3 Unit Analysis III: Weight 427 6.4 Converting Between the Two Systems and Temperature 6.5 Operations with Time and Mixed Units Summary 447 Review 451 Cumulative Review 453 Test 454 Projects 455

441

433

vii

viii

Contents

7

Introduction to Algebra

457

Introduction 457 7.1 Positive and Negative Numbers

459

7.2 Addition with Negative Numbers 469 7.3 Subtraction with Negative Numbers

479

7.4 Multiplication with Negative Numbers 7.5 Division with Negative Numbers 7.6 Simplifying Algebraic Expressions

489

497 503

Summary 509 Review

511

Cumulative Review 513 Test

515

Projects 517

8

Solving Equations

519

Introduction 519 8.1 The Distributive Property and Algebraic Expressions 8.2 The Addition Property of Equality

533

8.3 The Multiplication Property of Equality 8.4 Linear Equations in One Variable 8.5 Applications

541

549

557

8.6 Evaluating Formulas

569

Summary 579 Review

581

Cumulative Review 582 Test

584

Projects 585

Appendix A – Resources 587 Appendix B – One Hundred Addition Facts 588 Appendix C – One Hundred Multiplication Facts 589 Solutions to Selected Practice Problems S-1 Answers to Odd-Numbered Problems A-1 Index I-1

521

Preface to the Instructor I have a passion for teaching mathematics. That passion carries through to my textbooks. My goal is a textbook that is user-friendly for both students and instructors. For students, this book forms a bridge to beginning algebra with clear, concise writing, continuous review, and interesting applications. For the instructor, I build features into the text that reinforce the habits and study skills we know will bring success to our students. The seventh edition of Basic Mathematics builds upon these strengths.

Applying the Concepts Students are always curious about how the mathematics they are learning can be applied, so we have included applied problems in most of the problem sets in the book and have labeled them to show students the array of uses of mathematics. These applied problems are written in an inviting way, many times accompanied by new interesting illustrations to help students overcome some of the apprehension associated with application problems.

Getting Ready for the Next Section Many students think of mathematics as a collection of discrete, unrelated topics. Their instructors know that this is not the case. The new Getting Ready for the Next Section problems reinforce the cumulative, connected nature of this course by showing how the concepts and techniques flow one from another throughout the course. These problems review all of the material that students will need in order to be successful, forming a bridge to the next section, gently preparing students to move forward.

Maintaining Your Skills One of the major themes of our book is continuous review. We strive to continuously hone techniques learned earlier by keeping the important concepts in the forefront of the course. The Maintaining Your Skills problems review material from the previous chapter, or they review problems that form the foundation of the course—the problems that you expect students to be able to solve when they get to the next course.

The Basic Mathematics Course as a Bridge to Further Success Basic mathematics is a bridge course. The course and its syllabus bring the student to the level of ability required of college students, while getting them ready to make a successful start in introductory algebra.

Our Proven Commitment to Student Success After five successful editions, we have developed several interlocking, proven features that will improve students’ chances of success in the course. We place practical, easily understood study skills in the first five chapters scattered throughout the sections. Here are some of the other, important success features of the book.

Chapter Pretest These are meant as a diagnostic test taken before the starting work in the chapter. Much of the material here is learned in the chapter so proficiency on the pretests is not necessary.

ix

x

Preface to the Instructor

Getting Ready for Chapter X This is a set of problems from previous chapters that students need in order to be successful in the current chapter. These are review problems intended to reinforce the idea that all topics in the course are built on previous topics.

Getting Ready for Class Just before each problem set is a list of four questions under the heading Getting Ready for Class. These problems require written responses from students and are to be done before students come to class. The answers can be found by reading the preceding section. These questions reinforce the importance of reading the section before coming to class.

Blueprint for Problem Solving Found in the main text, this feature is a detailed outline of steps required to successfully attempt application problems. Intended as a guide to problem solving in general, the blueprint takes the student through the solution process to various kinds of applications.

End-of-Chapter Summary, Review, and Assessment We have learned that students are more comfortable with a chapter that sums up what they have learned thoroughly and accessibly, and reinforces concepts and techniques well. To help students grasp concepts and get more practice, each chapter ends with the following features that together give a comprehensive reexamination of the chapter.

Chapter Summary The chapter summary recaps all main points from the chapter in a visually appealing grid. In the margin, next to each topic, is an example that illustrates the type of problem associated with the topic being reviewed. Our way of summarizing shows students that concepts in mathematics do relate— and that mastering one concept is a bridge to the next. When students prepare for a test, they can use the chapter summary as a guide to the main concepts of the chapter.

Chapter Review Following the chapter summary in each chapter is the chapter review. It contains an extensive set of problems that review all the main topics in the chapter. This feature can be used flexibly, as assigned review, as a recommended self-test for students as they prepare for examinations, or as an in-class quiz or test.

Cumulative Review Starting in Chapter 2, following the chapter review in each chapter is a set of problems that reviews material from all preceding chapters. This keeps students current with past topics and helps them retain the information they study.

Chapter Test A set of problems representative of all the main points of the chapter. These don’t contain as many problems as the chapter review, and should be completed in 50 minutes.

Chapter Projects Each chapter closes with a pair of projects. One is a group project, suitable for students to work on in class. Group projects list details about number of participants, equipment, and time, so that instructors can determine how well the project fits into their classroom. The second project is a research project for students to do outside of class and tends to be open ended.

Preface to the Instructor

Additional Features of the Book Facts from Geometry Many of the important facts from geometry are listed under this heading. In most cases, an example or two accompanies each of the facts to give students a chance to see how topics from geometry are related to the algebra they are learning.

A Glimpse of Algebra These sections, found in most chapters, show how some of the material in the chapter looks when it is extended to algebra.

Chapter Openings Each chapter opens with an introduction in which a realworld application is used to stimulate interest in the chapter. We expand on these opening applications later in the chapter.

Descriptive Statistics Beginning in Chapter 1 and then continuing through the rest of the book, students are introduced to descriptive statistics. In Chapter 1 we cover tables and bar charts, as well as mean, median, and mode. These topics are carried through the rest of the book. Along the way we add to the list of descriptive statistics by including scatter diagrams and line graphs.

Supplements for the Instructor Please contact your sales representative.

Annotated Instructor's Edition

ISBN-10: 049555975X | ISBN-13: 9780495559757

This special instructor's version of the text contains answers next to all exercises and instructor notes at the appropriate location.

Complete Solutions Manual

ISBN-10: 0495828858 | ISBN-13: 9780495828853

This manual contains complete solutions for all problems in the text.

Enhanced WebAssign ISBN-10: 049582898X | ISBN-13: 9780495828983 Enhanced WebAssign 1-Semester Printed Access Card for Lower Level Math ISBN-10: 0495390801 | ISBN-13: 9780495390800 Enhanced WebAssign, used by over one million students at more than 1,100 institutions, allows you to assign, collect, grade, and record homework assignments via the web. This proven and reliable homework system includes thousands of algorithmically generated homework problems, links to relevant textbook sections, video examples, problem-specific tutorials, and more.

ExamView® Algorithmic Equation ISBN-10: 0495829498 | ISBN-13: 9780495829492 Create, deliver, and customize tests and study guides (both print and online) in minutes with this easy-to-use assessment and tutorial system.

PowerLecture with JoinIn® and ExamView® Algorithmic Equations ISBN-10: 049582951X | ISBN-13: 9780495829515

Text-Specific Videos

ISBN-10: 0495828939 | ISBN-13: 9780495828938

This set of text-specific videos features segments taught by the author, workedout solutions to many examples in the book. Available to instructors only.

xi

xii

Preface to the Instructor

Supplements for the Student Enhanced WebAssign 1-Semester Printed Access Card for Lower Level Math ISBN-10: 0495390801 | ISBN-13: 9780495390800 Enhanced WebAssign, used by over one million students at more than 1,100 institutions, allows you to assign, collect, grade, and record homework assignments via the web. This proven and reliable homework system includes thousands of algorithmically generated homework problems, links to relevant textbook sections, video examples, problem-specific tutorials, and more.

Student Solutions Manual ISBN-10: 0495559768 | ISBN-13: 9780495559764 This manual contains complete annotated solutions to all odd problems in the problem sets and all chapter review and chapter test exercises.

Acknowledgments I would like to thank my editor at Cengage Learning, Marc Bove, for his help and encouragement with this project. Many thanks also to Rich Jones, my developmental editor, for his suggestions on content, and his availability for consulting. Ellena Reda contributed both new ideas and exercises to this revision. Devin Christ, the head of production at our office, was a tremendous help in organizing and planning the details of putting this book together. Mary Gentilucci, Michael Landrum and Tammy Fisher-Vasta assisted with error checking and proofreading. Special thanks to my other friends at Cengage Learning: Sam Subity and Shaun Williams for handling the media and ancillary packages on this project, and Hal Humphrey, my project manager, who did a great job of coordinating everyone and everything in order to publish this book. Finally, I am grateful to the following instructors for their suggestions and comments: Patricia Clark, Sinclair CC; Matthew Hudock, St. Phillip’s College; Bridget Young, Suffolk County CC; Bettie Truitt, Black Hawk College; Armando Perez, Laredo CC; Diane Allen, College of Technology Idaho State; Jignasa Rami, CCBC Catonsville; Yon Kim, Passaic Community College; Elizabeth Chu, Suffolk County CC, Ammerman; Marilyn Larsen, College of the Mainland; Sherri Ucravich, University of Wisconsin; Scott Beckett, Jacksonville State University; Nimisha Raval, Macon Technical Institute; Gary Franchy, Davenport University, Warren; Debbi Loeffler, CC of Baltimore County; Scott Boman, Wayne County CC; Dayna Coker, Southwestern Oklahoma State; Annette Wiesner, University of Wisconsin; Anne Kmet, Grossmont College; Mary Wagner-Krankel, St. Mary's University; Joseph Deguzman, Riverside CC, Norco; Deborah McKee, Weber State University; Gail Burkett, Palm Beach CC; Lee Ann Spahr, Durham Technical CC; Randall Mills, KCTCS Big Sandy CC/Tech; Jana Bryant, Manatee CC; Fred Brown, University of Maine, Augusta; Jeff Waller, Grossmont College; Robert Fusco, Broward CC, FL; Larry Perez, Saddleback College, CA; Victoria Anemelu, San Bernardino Valley, CA; John Close, Salt Lake CC, UT; Randy Gallaher, Lewis and Clark CC; Julia Simms, Southern Illinois U; Julianne Labbiento, Lehigh Carbon CC; Joanne Kendall, Cy-Fair College; Ann Davis, Northeastern Tech. Pat. McKeague November 2008

Preface to the Student I often find my students asking themselves the question “Why can’t I understand this stuff the first time?” The answer is “You’re not expected to.” Learning a topic in mathematics isn’t always accomplished the first time around. There are many instances when you will find yourself reading over new material a number of times before you can begin to work problems. That’s just the way things are in mathematics. If you don’t understand a topic the first time you see it, that doesn’t mean there is something wrong with you. Understanding mathematics takes time. The process of understanding requires reading the book, studying the examples, working problems, and getting your questions answered.

How to Be Successful in Mathematics 1. If you are in a lecture class, be sure to attend all class sessions on time. You cannot know exactly what goes on in class unless you are there. Missing class and then expecting to find out what went on from someone else is not the same as being there yourself.

2. Read the book. It is best to read the section that will be covered in class beforehand. Reading in advance, even if you do not understand everything you read, is still better than going to class with no idea of what will be discussed.

3. Work problems every day and check your answers. The key to success in mathematics is working problems. The more problems you work, the better you will become at working them. The answers to the odd-numbered problems are given in the back of the book. When you have finished an assignment, be sure to compare your answers with those in the book. If you have made a mistake, find out what it is, and correct it.

4. Do it on your own. Don’t be misled into thinking someone else’s work is your own. Having someone else show you how to work a problem is not the same as working the same problem yourself. It is okay to get help when you are stuck. As a matter of fact, it is a good idea. Just be sure you do the work yourself.

5. Review every day. After you have finished the problems your instructor has assigned, take another 15 minutes and review a section you have already completed. The more you review, the longer you will retain the material you have learned.

6. Don’t expect to understand every new topic the first time you see it. Sometimes you will understand everything you are doing, and sometimes you won’t. That’s just the way things are in mathematics. Expecting to understand each new topic the first time you see it can lead to disappointment and frustration. The process of understanding takes time. It requires that you read the book, work problems, and get your questions answered.

7. Spend as much time as it takes for you to master the material. No set formula exists for the exact amount of time you need to spend on mathematics to master it. You will find out as you go along what is or isn’t enough time for you. If you end up spending 2 or more hours on each section in order to master the material there, then that’s how much time it takes; trying to get by with less will not work.

8. Relax. It’s probably not as difficult as you think.

xiii

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1

Whole Numbers

Chapter Outline 1.1 Place Value and Names for Numbers 1.2 Addition with Whole Numbers, and Perimeter 1.3 Rounding Numbers, Estimating Answers, and Displaying Information 1.4 Subtraction with Whole Numbers Image © 2008 DigitalGlobe

1.5 Multiplication with Whole Numbers 1.6 Division with Whole Numbers

Introduction The Hoover Dam, as shown in an image from Google Earth, sits on the border of Nevada and Arizona and was the largest producer of hydroelectric power in the

1.7 Exponents, Order of Operations, and Averages 1.8 Area and Volume

United States when it was completed in 1935. Hydroelectric power is the most widely used form of renewable energy today, accounting for about 19% of the world’s electricity. Hydroelectricity is a very clean source of power as it does not produce carbon dioxide or any waste products.

Renewable Energy Breakdown Of the energy consumed in 2006 in the US only 7% was renewable energy. Below is the breakdown of how that energy is created. Hydroelectric 42% Wind 5% Biomass 48% Geothermal 5% Solar 1% Source: Energy Information Adminstration 2006

As the chart indicates, the demand for energy is soaring, and developing new sources of energy production is more important than ever. In this chapter we will begin reading and understanding this type of chart.

1

Chapter Pretest The pretest below contains problems that are representative of the problems you will find in the chapter. Those of you studying on your own, or working in a self-paced course, can use the pretest to determine which parts of the chapter will require the most work on your part.

1. Write 7,062 in expanded form.

2. Write 3,409,021 in words.

3. Write eighteen thousand, five hundred seven with digits instead of words.

4. Add.

5. Add.

6. Subtract.

7. Subtract.

341

1,029

512

1,700

256 

4,381 

301 

1,436 

8. Multiply.

9. Multiply.

27

536

 8 

 40 

10. Divide.

11. Divide.

185 7 6 

234 ,0 1 8 

Round.

12. 513 to the nearest ten

13. 6,798 to the nearest hundred

Simplify.

14. 7  3  23

15. 4  5[2  6(9  7)]

16. Find the mean, the median, and range for 4, 5, 7, 9, 15. 17. Write the expression using symbols, then simplify. 6 times the difference of 12 and 8.

Getting Ready for Chapter 1 To get started in this book, we assume that you can do simple addition and multiplication problems. To check to see that you are ready for the chapter, fill in each of the tables below. If you have difficulty, you can find further practice in Appendix A and Appendix B at the back of the book. TABLE 1

TABLE 2

Addition Facts 

2

0

1

2

3

4

5

Multiplication Facts 6

7

8

9



0

0

1

1

2

2

3

3

4

4

5

5

6

6

7

7

8

8

9

9

Chapter 1 Whole Numbers

0

1

2

3

4

5

6

7

8

9

Place Value and Names for Numbers

1.1 Objectives A State the place value for a digit in a

Introduction . . .

number written in standard notation.

The two diagrams below are known as Pascal’s triangle, after the French mathematician and philosopher Blaise Pascal (1623–1662). Both diagrams contain the same information. The one on the left contains numbers in our number system; the one on the right uses numbers from Japan in 1781.

1 1 1 1

B

Write a whole number in expanded form.

C D

Write a number in words. Write a number from words.

1 2

3

1 3

1 1 4 6 4 1 1 5 10 10 5 1 1 6 15 20 15 6 1 1 7 21 35 35 21 7 1

Examples now playing at

MathTV.com/books

PASCAL’S TRIANGLE IN JAPAN From Mural Chu zen’s Sampo 苶 Do 苶shi-mon (1781)

A Place Value Our number system is based on the number 10 and is therefore called a “base 10” number system. We write all numbers in our number system using the digits 0, 1, 2, 3, 4, 5, 6, 7, 8, and 9. The positions of the digits in a number determine the values of the digits. For example, the 5 in the number 251 has a different value from the 5 in the number 542. The place values in our number system are as follows: The first digit on the right is in the ones column. The next digit to the left of the ones column is in the tens column. The next digit to the left is in the hundreds column. For a number like 542, the digit 5 is in the hundreds column, the 4 is in the tens column, and the 2 is in the ones column. If we keep moving to the left, the columns increase in value. The table shows the name and value of each of the first seven columns in our number system:

Millions Column 1,000,000

Hundred Thousands Column

Ten Thousands Column

Thousands Column

Hundreds Column

Tens Column

Ones Column

100,000

10,000

1,000

100

10

1

EXAMPLE 1

Note

Next to each Example in the text is a Practice Problem with the same number. After you read through an Example, try the Practice Problem next to it. The answers to the Practice Problems are at the bottom of the page. Be sure to check your answers as you work these problems. The worked-out solutions to all Practice Problems with more than one step are given in the back of the book. So if you find a Practice Problem that you cannot work correctly, you can look up the correct solution to that problem in the back of the book.

PRACTICE PROBLEMS Give the place value of each digit in the number 305,964.

SOLUTION Starting with the digit at the right, we have:

1. Give the place value of each digit in the number 46,095.

4 in the ones column, 6 in the tens column, 9 in the hundreds column, 5 in the thousands column, 0 in the ten thousands column, and 3 in the hundred thousands column.

Answer 1. 5 ones, 9 tens, 0 hundreds, 6 thousands, 4 ten thousands

1.1 Place Value and Names for Numbers

3

4

Chapter 1 Whole Numbers

Large Numbers The photograph shown here was taken by the Hubble telescope in April 2002. The object in the photograph is called the Cone Nebula. In astronomy, distances to objects like the Cone Nebula are given in light-years, the distance light travels in a year. If we assume light travels 186,000 miles in one second, then a light-year is 5,865,696,000,000 miles; that is 5 trillion, 865 billion, 696 million miles To find the place value of digits in large numbers, we can use Table 1. Note how NASA

the Hundreds, Thousands, Millions, Billions, and Trillions categories are each broken into Ones, Tens, and Hundreds. Note also that we have written the digits for our light-year in the last row of the table. TABLE 1

Trillions

Millions

Thousands

Hundreds

Ones

Hundreds

Tens

Ones

Hundreds

Tens

Ones

Hundreds

Tens

Ones

Hundreds

Tens

Ones

digit in the number 21,705,328,456.

Tens

Hundreds

2. Give the place value of each

Billions

5

8

6

5

6

9

6

0

0

0

0

0

0

EXAMPLE 2

Give the place value of each digit in the number

73,890,672,540.

Ten Billions

Billions

Hundred Millions

Ten Millions

Millions

Hundred Thousands

Ten Thousands

Thousands

Hundreds

Tens

Ones

SOLUTION The following diagram shows the place value of each digit.

7

3,

8

9

0,

6

7

2,

5

4

0

B Expanded Form We can use the idea of place value to write numbers in expanded form. For example, the number 542 can be written in expanded form as 542  500  40  2 because the 5 is in the hundreds column, the 4 is in the tens column, and the 2 is in the ones column. 3. Write 3,972 in expanded form. Answers 2. 6 ones, 5 tens, 4 hundreds, 8 thousands, 2 ten thousands, 3 hundred thousands, 5 millions, 0 ten millions, 7 hundred millions, 1 billion, 2 ten billions 3. 3,000  900  70  2

Here are more examples of numbers written in expanded form.

EXAMPLE 3 SOLUTION

Write 5,478 in expanded form.

5,478  5,000  400  70  8

We can use money to make the results from Example 3 more intuitive. Suppose you have $5,478 in cash as follows:

5

1.1 Place Value and Names for Numbers

$5,000

$400

$70

$8

Using this diagram as a guide, we can write $5,478  $5,000  $400  $70  $8 which shows us that our work writing numbers in expanded form is consistent with our intuitive understanding of the different denominations of money.

EXAMPLE 4 SOLUTION

4. Write 271,346 in expanded form.

354,798  300,000  50,000  4,000  700  90  8

EXAMPLE 5 SOLUTION

Write 354,798 in expanded form.

Write 56,094 in expanded form.

5. Write 71,306 in expanded form.

Notice that there is a 0 in the hundreds column. This means we have

0 hundreds. In expanded form we have 8m

56,094  50,000  6,000  90  4

Note that we don’t have to include the 0 hundreds

EXAMPLE 6 SOLUTION

Write 5,070,603 in expanded form.

The columns with 0 in them will not appear in the expanded form.

6. Write 4,003,560 in expanded form.

5,070,603  5,000,000  70,000  600  3

STUDY SKILLS Some of the students enrolled in my mathematics classes develop difficulties early in the course. Their difficulties are not associated with their ability to learn mathematics; they all have the potential to pass the course. Research has identified three variables that affect academic achievement. These are (1) how much math you know before entering a course, (2) the quality of instruction (classroom atmosphere, teaching style, textbook content and format), and (3) your academic self concept, attitude, anxiety, and study habits. As a student, you have the most control over the last variable. Your academic self concept is a significant predictor of mathematics achievement. Students who get off to a poor start do so because they have not developed the study skills necessary to be successful in mathematics. Throughout this textbook you will find tips and things you can do to begin to develop effective study skills and improve your academic self concept.

Put Yourself on a Schedule The general rule is that you spend two hours on homework for every hour you are in class. Make a schedule for yourself in which you set aside two hours each day to work on this course. Once you make the schedule, stick to it. Don’t just complete your assignments and then stop. Use all the time you have set aside. If you complete the assignment and have time left over, read the next section in the book, and then work more problems. As the course progresses you may find that two hours a day is not enough time to master the material in this course. If it takes you longer than two hours a day to reach your goals for this course, then that’s how much time it takes. Trying to get by with less will not work.

Answers 4. 200,000  70,000  1,000  300  40  6

5. 70,000  1,000  300  6 6. 4,000,000  3,000  500  60

6

Chapter 1 Whole Numbers

C Writing Numbers in Words The idea of place value and expanded form can be used to help write the names for numbers. Naming numbers and writing them in words takes some practice. Let’s begin by looking at the names of some two-digit numbers. Table 2 lists a few. Notice that the two-digit numbers that do not end in 0 have two parts. These parts are separated by a hyphen.

TABLE 2

Number

In English

25 47 93 88

Twenty-five Forty-seven Ninety-three Eighty-eight

Number

In English

30 62 77 50

Thirty Sixty-two Seventy-seven Fifty

The following examples give the names for some larger numbers. In each case the names are written according to the place values given in Table 1. 7. Write each number in words. a. 724 b. 595 c. 307

EXAMPLE 7

Write each number in words.

a. 452

SOLUTION

b. 397

c. 608

a. Four hundred fifty-two b. Three hundred ninety-seven c. Six hundred eight

8. Write each number in words. a. 4,758 b. 62,779 c. 305,440

EXAMPLE 8

Write each number in words.

a. 3,561

SOLUTION

b. 53,662

c. 547,801

a. Three thousand, five hundred sixty-one h

Notice how the comma separates the thousands from the hundreds b. Fifty-three thousand, six hundred sixty-two 9. Write each number in words. a. 707,044,002 b. 452,900,008 c. 4,008,002,001

c. Five hundred forty-seven thousand, eight hundred one

EXAMPLE 9

Write each number in words.

a. 507,034,005 Answers 7. a. Seven hundred twenty-four b. Five hundred ninety-five c. Three hundred seven 8. a. Four thousand, seven b. c. 9. a.

b.

c.

hundred fifty-eight Sixty-two thousand, seven hundred seventy-nine Three hundred five thousand, four hundred forty Seven hundred seven million, forty-four thousand, two Four hundred fifty-two million, nine hundred thousand, eight Four billion, eight million, two thousand, one

b. 739,600,075 c. 5,003,007,006

SOLUTION

a. Five hundred seven million, thirty-four thousand, five b. Seven hundred thirty-nine million, six hundred thousand, seventy-five c. Five billion, three million, seven thousand, six

7

1.1 Place Value and Names for Numbers

STUDY SKILLS Find Your Mistakes and Correct Them There is more to studying mathematics than just working problems. You must always check your answers with the answers in the back of the book. When you have made a mistake, find out what it is, and then correct it. Making mistakes is part of the process of learning mathematics. I have never had a successful student who didn’t make mistakes—lots of them. Your mistakes are your guides to understanding; look forward to them.

Here is a practical reason for being able to write numbers in word form.

D Writing Numbers from Words The next examples show how we write a number given in words as a number written with digits.

EXAMPLE 10

Write five thousand, six hundred forty-two, using digits

hundred twenty-one using digits instead of words.

instead of words.

SOLUTION

Five thousand, six hundred forty-two 5,

EXAMPLE 11

6

42

Write each number with digits instead of words.

a. Three million, fifty-one thousand, seven hundred b. Two billion, five c. Seven million, seven hundred seven SOLUTION

10. Write six thousand, two

a. 3,051,700

11. Write each number with digits instead of words.

a. Eight million, four thousand, two hundred

b. Twenty-five million, forty c. Nine million, four hundred thirty-one

b. 2,000,000,005 c. 7,000,707

Answers 10. 6,221 11. a. 8,004,200 b. 25,000,040 c. 9,000,431

8

Chapter 1 Whole Numbers

Sets and the Number Line In mathematics a collection of numbers is called a set. In this chapter we will be working with the set of counting numbers and the set of whole numbers, which are defined as follows:

Note

Counting numbers  {1, 2, 3, . . .}

Counting numbers are also called natural numbers.

Whole numbers  {0, 1, 2, 3, . . .} The dots mean “and so on,” and the braces { } are used to group the numbers in the set together. Another way to visualize the whole numbers is with a number line. To draw a number line, we simply draw a straight line and mark off equally spaced points along the line, as shown in Figure 1. We label the point at the left with 0 and the rest of the points, in order, with the numbers 1, 2, 3, 4, 5, and so on.

0

1

2

3

4

5

FIGURE 1 The arrow on the right indicates that the number line can continue in that direction forever. When we refer to numbers in this chapter, we will always be referring to the whole numbers.

STUDY SKILLS Gather Information on Available Resources You need to anticipate that you will need extra help sometime during the course. There is a form to fill out in Appendix A to help you gather information on resources available to you. One resource is your instructor; you need to know your instructor’s office hours and where the office is located. Another resource is the math lab or study center, if they are available at your school. It also helps to have the phone numbers of other students in the class, in case you miss class. You want to anticipate that you will need these resources, so now is the time to gather them together.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Give the place value of the 9 in the number 305,964. 2. Write the number 742 in expanded form. 3. Place a comma and a hyphen in the appropriate place so that the number 2,345 is written correctly in words below: two thousand three hundred forty five 4. Is there a largest whole number?

1.1 Problem Set

Problem Set 1.1 A Give the place value of each digit in the following numbers. [Examples 1, 2] 1. 78

2. 93

3. 45

7. 608

8. 450

9. 2,378

4. 79

10. 6,481

5. 348

6. 789

11. 273,569

12. 768,253

Give the place value of the 5 in each of the following numbers.

13. 458,992

14. 75,003,782

15. 507,994,787

16. 320,906,050

17. 267,894,335

18. 234,345,678,789

19. 4,569,000

20. 50,000

B Write each of the following numbers in expanded form. [Examples 3–6] 21. 658

22. 479

23. 68

24. 71

25. 4,587

26. 3,762

27. 32,674

28. 54,883

29. 3,462,577

30. 5,673,524

31. 407

32. 508

33. 30,068

34. 50,905

35. 3,004,008

36. 20,088,060

9

10

Chapter 1 Whole Numbers

C Write each of the following numbers in words. [Examples 7–9] 37. 29

38. 75

39. 40

40. 90

41. 573

42. 895

43. 707

44. 405

45. 770

46. 450

47. 23,540

48. 56,708

49. 3,004

50. 5,008

51. 3,040

52. 5,080

53. 104,065,780

54. 637,008,500

55. 5,003,040,008

56. 7,050,800,001

57. 2,546,731

58. 6,998,454

D Write each of the following numbers with digits instead of words. [Examples 10, 11] 59. Three hundred twenty-five

60. Forty-eight

61. Five thousand, four hundred thirty-two

62. One hundred twenty-three thousand, sixty-one

63. Eighty-six thousand, seven hundred sixty-two

64. One hundred million, two hundred thousand, three hundred

65. Two million, two hundred

66. Two million, two

67. Two million, two thousand, two hundred

68. Two billion, two hundred thousand, two hundred two

1.1 Problem Set

11

Applying the Concepts 69. The illustration shows the average income of workers 18 and older by education.

information in the given illustration:

Such Great Heights

Who’s in the Money? $93,333

100,000 80,000

40,000 20,000 0

Taipei 101 Taipei, Taiwan

$67,073

1,483 ft

High School Grad/ GED

Sears Tower Chicago, USA

1,450 ft

$28,631

$19,041

No H.S. Diploma

Petronas Tower 1 & 2 Kuala Lumpur, Malaysia

1,670 ft

$51,568

60,000

70. Write the following numbers in words from the

Bachelor’s Degree

Master’s Degree

PhD Source: www.tenmojo.com

Source: U.S. Census Bureau

a. the height in feet of the Taipei 101 building in

Write the following numbers in words:

a. the average income of someone with only a high

Taipei, Taiwan

school education

b. the height in feet of the Sears Tower in Chicago, b. the average income of someone with a Ph.D.

71. MP3s A new MP3 player has the ability to hold over 125,000 songs. Write the place

Illinois

72. Music Downloads The top three downloaded songs for

iPod

Music

>

Photos Extras Settings

> > >

value of the 1 in the number of songs.

downloads. Write the place value of the 3 in the MENU

73. Baseball Salaries According to mlb.com, major league baseball’s 2008 average player salary was $3,173,403, representing an increase of 7% from the previous season’s average. Write 3,173,403 in words.

Average Player Salary ‘07 ‘08

$3,173,403 7% increase

one month on Amazon.com had a combined 450,320 number of downloads.

74. Astronomy The distance from the sun to the earth is 92,897,416 miles. Write this number in expanded form.

12

Chapter 1 Whole Numbers

75. Web Searches The phrase “math help” was searched

76. Web Searches The phrase “math help” was searched

approximately 21,480 times in one month in 2008 from

approximately 6,180 times in one month in 2008 from

Google. Write this number in words.

Yahoo. Write this number in words.

Writing Checks In each of the checks below, fill in the appropriate space with the dollar amount in either digits or in words. 77.

78. 1002

Michael Smith 1221 Main Street Anytown, NY 11001

PAY TO THE ORDER OF

DATE

Sunshine Apartment Complex

$

0111332200233

DATE

PAY TO THE ORDER OF

750 . 00

Electric and Gas Company Two hundred sixteen dollars and no cents

DOLLARS 01001

1003

Michael Smith 1221 Main Street Anytown, NY 11001

7/8/08

01001

1142232

0111332200233

7/8/08

$ DOLLARS

1142232

Populations of Countries The table below gives estimates of the populations of some countries for mid-year 2008. The first column under Population gives the population in digits. The second column gives the population in words. Fill in the blanks.

Country

Population Digits

United States

79. United States

Three hundred four million

80. People’s Republic of China

One billion, three hundred thirty million

81. Japan

127,000,000

82. United Kingdom

61,000,000

United Kingdom 61,000,000

Words

China

Japan 127,000,000

(From U.S. Census Bureau, International Data Base)

Populations of Cities The table below gives estimates of the populations of some cities for mid-year 2008. The first column under Population gives the population in digits. The second column gives the population in words. Fill in the blanks.

City

Population Digits

Thirty-six million

84. Los Angeles

Eighteen million 10,900,000

London

18,000,000

7,500,000

Tokyo 36,000,000

Words

83. Tokyo

85. Paris

Los Angeles

Paris 10,900,000

86. London

7,500,000

Addition with Whole Numbers, and Perimeter Introduction . . . The chart shows the number of babies born in 2006, grouped together according

1.2 Objectives A Add whole numbers. B Understand the notation and vocabulary of addition.

to the age of mothers.

Who’s Having All the Babies Under 20:

441,832

20–29:

2,262,694

30–39:

1,449,039

40–54:

112,432

C D

Use the properties of addition.

E

Find the perimeter of a figure.

Find a solution to an equation by inspection.

Examples now playing at

MathTV.com/books

Source: National Center for Health Statistics, 2006

There is much more information available from the table than just the numbers shown. For instance, the chart tells us how many babies were born to mothers less than 30 years of age. But to find that number, we need to be able to do addition with whole numbers. Let’s begin by visualizing addition on the number line.

Facts of Addition Using lengths to visualize addition can be very helpful. In mathematics we generally do so by using the number line. For example, we add 3 and 5 on the number line like this: Start at 0 and move to 3, as shown in Figure 1. From 3, move 5 more units to the right. This brings us to 8. Therefore, 3  5  8.

3 units

Start

0

1

5 units

2

3

4

5

End

6

7

8

FIGURE 1

If we do this kind of addition on the number line with all combinations of the numbers 0 through 9, we get the results summarized in Table 1 on the next page. We call the information in Table 1 our basic addition facts. Your success with the examples and problems in this section depends on knowing the basic addition facts.

1.2 Addition with Whole Numbers, and Perimeter

13

14

Note

Table 1 is a summary of the addition facts that you must know in order to make a successful start in your study of basic mathematics. You must know how to add any pair of numbers that come from the list. You must be fast and accurate. You don’t want to have to think about the answer to 7  9. You should know it’s 16. Memorize these facts now. Don’t put it off until later. Appendix B at the back of the book has 100 problems on the basic addition facts for you to practice. You may want to go there now and work those problems.

Chapter 1 Whole Numbers

TABLE 1

ADDITION TABLE 

0

1

2

3

4

5

6

7

8

9

0 1 2 3 4 5 6 7 8 9

0 1 2 3 4 5 6 7 8 9

1 2 3 4 5 6 7 8 9 10

2 3 4 5 6 7 8 9 10 11

3 4 5 6 7 8 9 10 11 12

4 5 6 7 8 9 10 11 12 13

5 6 7 8 9 10 11 12 13 14

6 7 8 9 10 11 12 13 14 15

7 8 9 10 11 12 13 14 15 16

8 9 10 11 12 13 14 15 16 17

9 10 11 12 13 14 15 16 17 18

We read Table 1 in the following manner: Suppose we want to use the table to find the answer to 3  5. We locate the 3 in the column on the left and the 5 in the row at the top. We read across from the 3 and down from the 5. The entry in the table that is across from 3 and below 5 is 8.

A Adding Whole Numbers To add whole numbers, we add digits within the same place value. First we add the digits in the ones place, then the tens place, then the hundreds place, and so on.

PRACTICE PROBLEMS 1. Add: 63  25

Note

To show why we add digits with the same place value, we can write each number showing the place value of the digits: 43  4 tens  3 ones  52  5 tens  2 ones 9 tens  5 ones

EXAMPLE 1 SOLUTION

Add: 43  52

This type of addition is best done vertically. First we add the digits in

the ones place. 43  52 5 Then we add the digits in the tens place. 43  52 95

2. Add: 342  605

EXAMPLE 2 SOLUTION

Add: 165  801

Writing the sum vertically, we have 165  801 966 m888888888 Add ones place m88 m8888888

Answers 1. 88 2. 947

Add tens place Add hundreds place

15

1.2 Addition with Whole Numbers, and Perimeter

A Addition with Carrying In Examples 1 and 2, the sums of the digits with the same place value were always 9 or less. There are many times when the sum of the digits with the same place value will be a number larger than 9. In these cases we have to do what is called carrying in addition. The following examples illustrate this process.

EXAMPLE 3 SOLUTION

Add: 197  213  324

We write the sum vertically and add digits with the same place

value. 1

When we add the ones, we get 7  3  4  14 We write the 4 and carry the 1 to the tens column

197 213  324 4 11

We add the tens, including the 1 that was carried over from the last step. We get 13, so we write the 3 and carry the 1 to the hundreds column

197 213  324 34 11

We add the hundreds, including the 1 that was carried over from the last step

197 213  324

3. Add. a. 375  121  473 b. 495  699  978

Note

Notice that Practice Problem 3 has two parts. Part a is similar to the problem shown in Example 3. Part b is similar also, but a little more challenging in nature. We will do this from time to time throughout the text. If a practice problem contains more parts than the example to which it corresponds, then the additional parts cover the same concept, but are more challenging than Part a.

734

EXAMPLE 4 SOLUTION

Add: 46,789  2,490  864

We write the sum vertically—with the digits with the same place

4. Add. a. 57,904  7,193  655 b. 68,495  7,236  878  29  5

value aligned—and then use the shorthand form of addition. 1 m8888888

2

4

9

0

8

6

4

1

4

3

5

0 m888888888

9

m88888888888

8

m8

2

7

m8888

2

6 ,

m8888888

1

4

,

,

These are the numbers that have been carried

Write the 3; carry the 1 Write the 4; carry the 2 Write the 1; carry the 2 Write the 0; carry the 1 No carrying necessary

Ones Tens Hundreds Thousands Ten thousands

Adding numbers as we are doing here takes some practice. Most people don’t make mistakes in carrying. Most mistakes in addition are made in adding the numbers in the columns. That is why it is so important that you are accurate with the basic addition facts given in this chapter.

B Vocabulary The word we use to indicate addition is the word sum. If we say “the sum of 3 and 5 is 8,” what we mean is 3  5  8. The word sum always indicates addition. We can state this fact in symbols by using the letters a and b to represent numbers.

Answers 3. a. 969 b. 2,172 4. a. 65,752 b. 76,643

16

Chapter 1 Whole Numbers

Definition If a and b are any two numbers, then the sum of a and b is a  b. To find the sum of two numbers, we add them.

Table 2 gives some phrases and sentences in English and their mathematical equivalents written in symbols.

Note

TABLE 2

When mathematics is used to solve everyday problems, the problems are almost always stated in words. The translation of English to symbols is a very important part of mathematics.

In English

In Symbols

The sum of 4 and 1 4 added to 1 8 more than m x increased by 5 The sum of x and y The sum of 2 and 4 is 6.

4 1 m x x 2

     

1 4 8 5 y 4  6

C Properties of Addition Once we become familiar with addition, we may notice some facts about addition that are true regardless of the numbers involved. The first of these facts involves the number 0 (zero). Whenever we add 0 to a number, the result is the original number. For example, 707

033

and

Because this fact is true no matter what number we add to 0, we call it a property of 0.

Addition Property of 0 If we let a represent any number, then it is always true that a0a

and

0aa

In words: Adding 0 to any number leaves that number unchanged.

Note

When we use letters to represent numbers, as we do when we say “If a and b are any two numbers,” then a and b are called variables, because the values they take on vary. We use the variables a and b in the definitions and properties on this page because we want you to know that the definitions and properties are true for all numbers that you will encounter in this book.

A second property we notice by becoming familiar with addition is that the order of two numbers in a sum can be changed without changing the result. 358

and

538

4  9  13

and

9  4  13

This fact about addition is true for all numbers. The order in which you add two numbers doesn’t affect the result. We call this fact the commutative property of addition, and we write it in symbols as follows.

Commutative Property of Addition If a and b are any two numbers, then it is always true that abba In words: Changing the order of two numbers in a sum doesn’t change the result.

17

1.2 Addition with Whole Numbers, and Perimeter

STUDY SKILLS Accept Definitions It is important that you don’t overcomplicate definitions. When I tell my students that my name is Mr. McKeague, they don’t ask “why?” You should approach definitions in the same way. Just accept them as they are, and memorize them if you have to. If someone asks you what the commutative property is, you should be able to respond, “With addition, the commutative property says that if a and b are two numbers then a + b = b + a. In other words, you can change the order of two numbers you are adding without changing the result.”

EXAMPLE 5

Use the commutative property of addition to rewrite each

sum. a. 4  6

SOLUTION

b. 5  9

c. 3  0

d. 7  n

The commutative property of addition indicates that we can change

the order of the numbers in a sum without changing the result. Applying this

5. Use the commutative property of addition to rewrite each sum. a. 7  9 b. 6  3 c. 4  0 d. 5  n

property we have: a. 4  6  6  4 b. 5  9  9  5 c. 3  0  0  3 d. 7  n  n  7 Notice that we did not actually add any of the numbers. The instructions were to use the commutative property, and the commutative property involves only the order of the numbers in a sum.

The last property of addition we will consider here has to do with sums of more than two numbers. Suppose we want to find the sum of 2, 3, and 4. We could add 2 and 3 first, and then add 4 to what we get: (2  3)  4  5  4  9 Or, we could add the 3 and 4 together first and then add the 2: 2  (3  4)  2  7  9 The result in both cases is the same. If we try this with any other numbers, the

Note

This discussion is here to show why we write the next property the way we do. Sometimes it is helpful to look ahead to the property itself (in this case, the associative property of addition) to see what it is that is being justified.

same thing happens. We call this fact about addition the associative property of addition, and we write it in symbols as follows.

Associative Property of Addition If a, b, and c represent any three numbers, then (a  b)  c  a  (b  c) In words: Changing the grouping of three numbers in a sum doesn’t change the result.

Answer 5. a. 9  7 b. 3  6 c. 0  4 d. n  5

18

6. Use the associative property of addition to rewrite each sum. a. (3  2)  9 b. (4  10)  1 c. 5  (9  1) d. 3  (8  n)

Chapter 1 Whole Numbers

EXAMPLE 6

Use the associative property of addition to rewrite each

sum. a. (5  6)  7

SOLUTION

b. (3  9)  1

c. 6  (8  2)

d. 4  (9  n)

The associative property of addition indicates that we are free to

regroup the numbers in a sum without changing the result. a. (5  6)  7  5  (6  7) b. (3  9)  1  3  (9  1) c. 6  (8  2)  (6  8)  2 d. 4  (9  n)  (4  9)  n The commutative and associative properties of addition tell us that when adding whole numbers, we can use any order and grouping. When adding several numbers, it is sometimes easier to look for pairs of numbers whose sums are 10, 20, and so on.

EXAMPLE 7 7. Add. a. 6  2  4  8  3 b. 24  17  36  13

SOLUTION

Add: 9  3  2  7  1

We find pairs of numbers that we can add quickly: 88n

88n

88n

93271 888888 888888 88m 8 8 m  10  10  2  22

D Solving Equations

Note

The letter n as we are using it here is a variable, because it represents a number. In this case it is the number that is a solution to an equation.

We can use the addition table to help solve some simple equations. If n is used to represent a number, then the equation n35 will be true if n is 2. The number 2 is therefore called a solution to the equation, because, when we replace n with 2, the equation becomes a true statement: 235 Equations like this are really just puzzles, or questions. When we say, “Solve the equation n  3  5,” we are asking the question, “What number do we add to 3 to get 5?” When we solve equations by reading the equation to ourselves and then stating the solution, as we did with the equation above, we are solving the equation by inspection.

8. Use inspection to find the

EXAMPLE 8

solution to each equation. a. n  9  17 b. n  2  10 c. 8  n  9 d. 16  n  10

a. n  5  9 b. n  6  12 c. 4  n  5 d. 13  n  8

SOLUTION Answers 6. a. 3  (2  9) b. 4  (10  1) c. (5  9)  1 d. (3  8)  n 7. a. 23 b. 90 8. a. 8 b. 8 c. 1 d. 6

Find the solution to each equation by inspection.

We find the solution to each equation by using the addition facts

given in Table 1. a. The solution to n  5  9 is 4, because 4  5  9. b. The solution to n  6  12 is 6, because 6  6  12. c. The solution to 4  n  5 is 1, because 4  1  5. d. The solution to 13  n  8 is 5, because 13  5  8.

19

1.2 Addition with Whole Numbers, and Perimeter

E Perimeter FACTS FROM GEOMETRY Perimeter We end this section with an introduction to perimeter. Here we will find the perimeter of several different shapes called polygons. A polygon is a closed geometric figure, with at least three sides, in which each side is a straight line segment. The most common polygons are squares, rectangles, and triangles. Examples of these are shown in Figure 2.

square

rectangle

triangle

w s

Note

h

l

b FIGURE 2

In the square, s is the length of the side, and each side has the same length. In the rectangle, l stands for the length, and w stands for the width.

In the triangle, the small square where the broken line meets the base is the notation we use to show that the two line segments meet at right angles. That is, the height h and the base b are perpendicular to each other; the angle between them is 90°.

The width is usually the lesser of the two. The b and h in the triangle are the base and height, respectively. The height is always perpendicular to the base. That is, the height and base form a 90°, or right, angle where they meet.

Definition The perimeter of any polygon is the sum of the lengths of the sides, and it is denoted with the letter P.

EXAMPLE 9 a.

9. Find the perimeter of each

Find the perimeter of each geometric figure.

b.

c.

geometric figure.

36 yards

23 yards

a.

24 feet

24 yards

15 inches

24 yards

37 feet

7 feet 12 yards

b.

33 inches

SOLUTION In each case we find the perimeter by adding the lengths of all the sides.

88 inches a. The figure is a square. Because the length of each side in the

c.

square is the same, the perimeter is P  15  15  15  15  60 inches b. In the rectangle, two of the sides are 24 feet long, and the other two are 37 feet long. The perimeter is the sum of the lengths of

44 yards

66 yards 77 yards

the sides. P  24  24  37  37  122 feet c. For this polygon, we add the lengths of the sides together. The result is the perimeter. P  36  23  24  12  24  119 yards

Answer 9. a. 28 feet b. 242 inches c. 187 yards

20

Chapter 1 Whole Numbers

USING

TECHNOLOGY

Calculators From time to time we will include some notes like this one, which show how a calculator can be used to assist us with some of the calculations in the book. Most calculators on the market today fall into one of two categories: those with algebraic logic and those with function logic. Calculators with algebraic logic have a key with an equals sign on it. Calculators with function logic do not have an equals key. Instead they have a key labeled ENTER or EXE (for execute). Scientific calculators use algebraic logic, and graphing calculators, such as the TI-83, use function logic. Here are the sequences of keystrokes to use to work the problem shown in Part c of Example 9. Scientific Calculator:

36

Graphing Calculator:

36

 

23 23

 

24 24

 

12 12

 

24 24

 ENT

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. What number is the sum of 6 and 8? 2. Make up an addition problem using the number 456 that does not involve carrying. 3. Make up an addition problem using the number 456 that involves carrying from the ones column to the tens column only. 4. What is the perimeter of a geometric figure?

21

1.2 Problem Set

Problem Set 1.2 A Find each of the following sums. (Add.) [Examples 1–4] 1. 3  5  7

2. 2  8  6

3. 1  4  9

4. 2  8  3

5. 5  9  4  6

6. 8  1  6  2

7. 1  2  3  4  5

8. 5  6  7  8  9

9. 9  1  8  2

10. 7  3  6  4

A Add each of the following. (There is no carrying involved in these problems.) [Examples 1, 2] 11. 43

12. 56

13. 81

14. 37

15. 4,281

16. 2,749

25

23

17

22

3,016

1,250

17. 3,482

18. 2,496

19. 32

20. 521

21. 6,245

3,005

7,503

21

340

203

4,510

43

135

1,001

342

22.

27

A Add each of the following. (All problems involve carrying in at least one column.) [Examples 3, 4] 23. 49

24. 85

25. 74

26. 36

27. 682

28. 439

16

29

28

46

193

270

29. 638

30. 444

31. 4,963

32. 8,291

33. 6,205

34. 8,888

191

595

5,428

7,489

9,999

9,999

35. 56,789

36. 45,678

37. 52,468

38. 13,579

39. 4,296

40. 5,637

98,765

87,654

58,642

97,531

8,720

481

4,375

7,899

41. 4,994

42. 6,824

43. 12

44. 21

999

46. 646

449

371

34

43

444

464

9,449

4,857

56

65

555

525

78

87

222

252

47. 9,245 672

48.

45 9,876

8,341

54

27

6,789

45.

22

Chapter 1 Whole Numbers

B Complete the following tables. 49.

51.

50. First Number a

Second Number b

61 63 65 67

38 36 34 32

First Number a

Second Number b

9 36 81 144

16 64 144 256

Their Sum a+b

First Number a

Second Number b

10 20 30 40

45 35 25 15

First Number a

Second Number b

25 24 23 22

75 76 77 78

Their Sum a+b

52. Their Sum a+b

Their Sum a+b

C Rewrite each of the following using the commutative property of addition. [Example 5] 53. 5  9

54. 2  1

55. 3  8

56. 9  2

57. 6  4

58. 1  7

C Rewrite each of the following using the associative property of addition. [Example 6] 59. (1  2)  3

60. (4  5)  9

61. (2  1)  6

62. (2  3)  8

63. 1  (9  1)

64. 2  (8  2)

65. (4  n)  1

66. (n  8)  1

D Find a solution for each equation. [Example 8] 67. n  6  10

68. n  4  7

69. n  8  13

70. n  6  15

71. 4  n  12

72. 5  n  7

73. 17  n  9

74. 13  n  5

B Write each of the following expressions in words. Use the word sum in each case. [Table 2] 75. 4  9

76. 9  4

77. 8  1

78. 9  9

79. 2  3  5

80. 8  2  10

B Write each of the following in symbols. [Table 2] 81. a. The sum of 5 and 2 b. 3 added to 8

82. a. The sum of a and 4 b. 6 more than x

83. a. m increased by 1 b. The sum of m and n

84. a. The sum of 4 and 8 is 12. b. The sum of a and b is 6.

1.2 Problem Set

23

E Find the perimeter of each figure. The first four figures are squares. [Example 9] 85.

86.

87.

88.

2 ft

4 ft

9 in.

3 in.

89.

90.

1 yd

3 yd 5 yd 10 yd

91.

92.

4 in.

6 in.

5 in.

10 in.

12 in.

7 in.

E

Applying the Concepts

93. Classroom appliances use a lot of energy. You can save

94. The information in the illustration represents the

energy by unplugging or turning of unused appliances.

number of picture messages sent for the first nine

Use the information in the given illustration to find the

months of the year, in millions. Use the information to

following:

find the following:

Energy Estimates

A Picture’s Worth 1,000 Words

All units given as watts per hour. Ceiling fan Stereo Television VCR/DVD player

50

41

125

40

32

400 30

130 20

21

21

May

Jun

26

20

400 400

Printer Photocopier Coffee maker

10 10

1000

0

3 Jan

Feb

Mar

Apr

Jul

Aug

Sep

Source: dosomething.org 2008

a. the number of watts/hour saved by unplugging a DVD player and a television

b. the number of watts/hour saved by unplugging a ceiling fan and a coffee maker

a. the number of picture messages sent in all nine months

b. the number of picture messages sent in March and April

24

Chapter 1 Whole Numbers

95. Checkbook Balance On Monday Bob had a balance of

96. Number of Passengers A plane flying from Los Angeles

$241 in his checkbook. On Tuesday he made a deposit of

to New York left Los Angeles with 67 passengers on

$108, and on Thursday he wrote a check for $24. What

board. The plane stopped in Bakersfield and picked up

was the balance in his checkbook on Wednesday?

28 passengers, and then it stopped again in Dallas where 57 more passengers came on board. How many

ITS THAT AFFECT YOUR ACCOUNT

RECORD ALL CHARGES OR CRED NUMBER

DATE

DESCRIPTION OF TRANSACTION

1 /06 Deposit 1401 1 /18 Postage Stamps

PAYMENT/DEBIT (-)

$24 00

DEPOSIT/CREDIT (+)

$108 00

BALANCE

passengers were on the plane when it landed in New York?

$241 00 ? ?

97. College Costs According to data from The Chronicle of Higher Education, the most expensive college in the country is George Washington University in Washington, D.C. According to the university’s website, a student entering as a freshman during the 2008 – 09 academic year can expect to pay the expenses shown in the chart below:

2008-09 Costs for Attending George Washington University Tuition/Fees $40,392 Transportation $2,200 Health Insurance $1,800 Room and Board $13,600 Books/Supplies $1,185 Personal Expenses $3,200

a. What are the total of the expenses for one year at George Washington University? b. How much of these total expenses are college related? c. What is the total amount for expenses that are not directly related to attending this college?

98. Improving Your Quantitative Literacy Quantitative literacy is a subject discussed by many people involved in teaching mathematics. The person they are concerned with when they discuss it is you. We are going to work at improving your quantitative literacy, but before we do that we should answer the question, what is quantitative literacy? Lynn Arthur Steen, a noted mathematics educator, has stated that quantitative literacy is “the capacity to deal effectively with the quantitative aspects of life.”

a. Give a definition for the word quantitative. b. Give a definition for the word literacy. c. Are there situations that occur in your life that you find distasteful or that you try to avoid because they involve numbers and mathematics? If so, list some of them here. (For example, some people find the process of buying a car particularly difficult because they feel that the numbers and details of the financing are beyond them.)

Rounding Numbers, Estimating Answers, and Displaying Information

Objectives A Round whole numbers. B Estimate the answer to a problem.

Introduction . . . Many times when we talk about numbers, it is helpful to use numbers that have been rounded off, rather than exact

We l c o m e t o

numbers. For example, the city where I live has a population

San Luis Obispo

of 43,704. But when I tell people how large the city is, I usually say, “The population is about 44,000.” The number 44,000 is

1.3

Founded 1772

Population 43,704

Examples now playing at

the original number rounded to the nearest thousand. The

MathTV.com/books

number 43,704 is closer to 44,000 than it is to 43,000, so it is rounded to 44,000. We can visualize this situation on the number line.

Further

Closer

43,000

43,704

44,000

A Rounding The steps used in rounding numbers are given below.

Note

Strategy Rounding Whole Numbers To summarize, we list the following steps:

Step 1: Locate the digit just to the right of the place you are to round to.

After you have used the steps listed here to work a few problems, you will find that the procedure becomes almost automatic.

Step 2: If that digit is less than 5, replace it and all digits to its right with zeros.

Step 3: If that digit is 5 or more, replace it and all digits to its right with zeros, and add 1 to the digit to its left.

You can see from these rules that in order to round a number you must be told what column (or place value) to round to.

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

Round 5,382 to the nearest hundred.

There is a 3 in the hundreds column. We look at the digit just to its

1. Round 5,742 to the nearest a. hundred b. thousand

right, which is 8. Because 8 is greater than 5, we add 1 to the 3, and we replace the 8 and 2 with zeros: 8n

8n

Greater than 5

EXAMPLE 2 SOLUTION

n

5,400

Add 1 to get 4

to the nearest hundred 88

is

88

5,382

Put zeros here

Round 94 to the nearest ten.

There is a 9 in the tens column. To its right is 4. Because 4 is less

than 5, we simply replace it with 0:

Less than 5

is

90

to the nearest ten

8n

8n

94

2. Round 87 to the nearest a. ten b. hundred

Replaced with zero

1.3 Rounding Numbers, Estimating Answers, and Displaying Information

Answers 1. a. 5,700 b. 6,000 2. a. 90 b. 100

25

26

Chapter 1 Whole Numbers

3. Round 980 to the nearest a. hundred b. thousand

EXAMPLE 3 SOLUTION

Round 973 to the nearest hundred.

We have a 9 in the hundreds column. To its right is 7, which is

greater than 5. We add 1 to 9 to get 10, and then replace the 7 and 3 with zeros:

Add 1 to get 10

EXAMPLE 4 SOLUTION

88

88

Greater than 5

to the nearest hundred

Put zeros here

Round 47,256,344 to the nearest million.

We have 7 in the millions column. To its right is 2, which is less than

5. We simply replace all the digits to the right of 7 with zeros to get: 47,000,000

n

is

Less than 5

to the nearest million

88

8n

47,256,344

8n

nearest a. million b. ten thousand

88

n

4. Round 376,804,909 to the

1,000

n

is n

973

Leave as is

Replaced with zeros

Table 1 gives more examples of rounding.

TABLE 1

Rounded to the Nearest Original Number 6,914 8,485 5,555 1,234

Ten

Hundred

Thousand

6,910 8,490 5,560 1,230

6,900 8,500 5,600 1,200

7,000 8,000 6,000 1,000

House Payments $10,200 Taxes $6,137 Miscellaneous $6,142

Rule

Entertainment $2,142

If we are doing calculations and are asked to round our answer, we do all our

Car Expenses $4,847

arithmetic first and then round the result. That is, the last step is to round the answer; we don’t round the numbers first and then do the arithmetic.

Savings $2,149 Food $5,296

5. Use the pie chart above to answer these questions. a. To the nearest ten dollars, what is the total amount spent on food and car expenses? b. To the nearest hundred dollars, how much is spent on savings and taxes? c. To the nearest thousand dollars, how much is spent on items other than food and entertainment?

EXAMPLE 5

The pie chart in the margin shows how a family earning

$36,913 a year spends their money. a. To the nearest hundred dollars, what is the total amount spent on food and entertainment? b. To the nearest thousand dollars, how much of their income is spent on items other than taxes and savings?

SOLUTION

In each case we add the numbers in question and then round the

sum to the indicated place. a. We add the amounts spent on food and entertainment and then round that result to the nearest hundred dollars. Food Entertainment Total

Answers 3. a. 1,000 b. 1,000 4. a. 377,000,000 b. 376,800,000

$5,296 2,142 $7,438  $7,400 to the nearest hundred dollars

27

1.3 Rounding Numbers, Estimating Answers, and Displaying Information b. We add the numbers for all items except taxes and savings. House payments

$10,200

Food

5,296

Car expenses

4,847

Entertainment

2,142

Miscellaneous

6,142 $28,627  $29,000 to the nearest

Total

thousand dollars

B Estimating When we estimate the answer to a problem, we simplify the problem so that an approximate answer can be found quickly. There are a number of ways of doing this. One common method is to use rounded numbers to simplify the arithmetic necessary to arrive at an approximate answer, as our next example shows.

EXAMPLE 6

Estimate the answer to the following problem by

rounding each number to the nearest thousand. a. 5,287 2,561 888 4,898

rounding each number to the nearest thousand. 4,872 1,691 777  6,124

SOLUTION

We round each of the four numbers in the sum to the nearest

thousand. Then we add the rounded numbers. 4,872

rounds to

5,000

1,691

rounds to

2,000

777

rounds to

1,000

 6,124

rounds to

 6,000

b.

702 3,944 1,001 3,500

Note

14,000 We estimate the answer to this problem to be approximately 14,000. The actual answer, found by adding the original unrounded numbers, is 13,464. Here is a practical application for which the ability to estimate can be a useful tool.

EXAMPLE 7

6. Estimate the answer by first

On the way home from classes you stop at the local

grocery store to pick up a few things. You know that you have a $20.00 bill in

In Example 6 we are asked to estimate an answer, so it is okay to round the numbers in the problem before adding them. In Example 5 we are asked for a rounded answer, meaning that we are to find the exact answer to the problem and then round to the indicated place. In that case we must not round the numbers in the problem before adding.

your wallet. You pick up the following items: a loaf of wheat bread for $2.29, a gallon of milk for $3.96, a dozen eggs for $2.18, a pound of apples for $1.19, and a box of your favorite cereal for $4.59. Use estimation to determine if you will have enough to pay for your groceries when you get to the cashier.

SOLUTION

We round the items in our grocery cart off to the nearest dollar: wheat bread for $2.29

rounds to

$2.00

milk for $3.96

rounds to

$4.00

eggs for $2.18

rounds to

$2.00

apples for $1.19

rounds to

$1.00

 cereal for $4.59

rounds to

 $5.00 $14.00

We estimate our total to be $14.00. Thus, $20.00 will be enough to pay for the groceries. (The actual cost of the groceries is $14.21.)

Answer 5. a. $10,140 b. $8,300 c. $29,000 6. a. 14,000 b. 10,000

Chapter 1 Whole Numbers

DESCRIPTIVE STATISTICS Bar Charts The table and chart below give two representations for the amount of caffeine in five different drinks, one numeric and the other visual. 100

Instant coffee

70

Tea

50

Cocoa

5

Decaffeinated coffee

4

60

50

40 20 5

4 Decaf coffee

100

70

Cocoa

Brewed coffee

80

0 Tea

Caffeine (in milligrams)

Instant coffee

Beverage (6-ounce cup)

100

Brewed coffee

TABLE 2 Caffeine (in milligrams)

28

FIGURE 1 The diagram in Figure 1 is called a bar chart. The horizontal line below which the drinks are listed is called the horizontal axis, while the vertical line that is labeled from 0 to 100 is called the vertical axis.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Describe the process you would use to round the number 5,382 to the nearest thousand. 2. Describe the process you would use to round the number 47,256,344 to the nearest ten thousand. 3. Find a number not containing the digit 7 that will round to 700 when rounded to the nearest hundred. 4. When I ask a class of students to round the number 7,499 to the nearest thousand, a few students will give the answer as 8,000. In what way are these students using the rule for rounding numbers incorrectly?

1.3 Problem Set

Problem Set 1.3 A Round each of the numbers to the nearest ten. [Examples 1–5] 1. 42

2. 44

3. 46

4. 48

5. 45

6. 73

7. 77

8. 75

9. 458

10. 455

11. 471

12. 680

13. 56,782

14. 32,807

15. 4,504

16. 3,897

Round each of the numbers to the nearest hundred. [Examples 1–5]

17. 549

18. 954

19. 833

20. 604

21. 899

22. 988

23. 1090

24. 6,778

25. 5,044

26. 56,990

27. 39,603

28. 31,999

Round each of the numbers to the nearest thousand. [Examples 1–5]

29. 4,670

30. 9,054

31. 9,760

32. 4,444

33. 978

34. 567

35. 657,892

36. 688,909

37. 509,905

38. 608,433

39. 3,789,345

40. 5,744,500

29

30

Chapter 1 Whole Numbers

A Complete the following table by rounding the numbers on the left as indicated by the headings in the table. [Examples 1–5]

Rounded to the Nearest Original Number

41.

7,821

42.

5,945

43.

5,999

44.

4,353

45.

10,985

46.

11,108

47.

99,999

48.

95,505

Ten

Hundred

Thousand

B Estimating Estimate the answer to each of the following problems by rounding each number to the indicated place value and then adding. [Example 6]

49. hundred

50. thousand

51. hundred

52. hundred

750

1,891

472

275

765

422

601

 120

 3,223

536

744

 511

 298

53. thousand

54. thousand

55. hundred

399

56. ten thousand

25,399

9,999

9,999

7,601

8,888

8,888

72,560

18,744

7,777

7,777

 219,065

 6,298

 6,666

 6,666

57. ten thousand

58. ten

59. hundred

127,675

60. hundred

65,000

10,061

20,150

1,950

31,000

10,044

18,250

2,849

15,555

10,035

12,350

3,750

 72,000

 10,025

 30,450

 4,649

1.3 Problem Set

31

Applying the Concepts 61. Age of Mothers About 4 million babies were born in 2006. The chart shows the breakdown by mothers’ age and number of babies. Use the chart to answer the following questions.

a. What is the exact number of babies born in 2006?

Who’s Having All the Babies Under 20:

441,832

20–29:

2,262,694

30–39:

1,449,039

40–54:

112,432

Source: National Center for Health Statistics, 2006

b. Using your answer from Part a, is the statement “About 4 million babies were born in 2006” correct?

c. To the nearest hundred thousand, how many babies were born to mothers aged 20 to 29 in 2006?

d. To the nearest thousand, how many babies were born to mothers 40 years old or older?

62. Business Expenses The pie chart shows one year’s worth of expenses for a small business. Use the chart to answer the following questions.

Salaries $20,761

a. To the nearest hundred dollars, how much was spent on postage and supplies?

Supplies $11,456 Postage $3,792 Telephone $3,652 All Other Expenses $8,496 Rent and Utilities $7,499

b. Find the total amount spent, to the nearest hundred dollars, on rent and utilities and car expenses.

Car Expenses $3,205

c. To the nearest thousand dollars, how much was spent on items other than salaries and rent and utilities?

d. To the nearest thousand dollars, how much was spent on items other than postage, supplies, and car expenses?

32

Chapter 1 Whole Numbers

The bar chart below is similar to the one we studied in this section. It was given to me by a friend who owns and operates an alcohol dragster. The dragster contains a computer that gives information about each of his races. This particular race was run during the 1993 Winternationals. The bar chart gives the speed of a race car in a quarter-mile drag race every second during the race. The horizontal lines have been added to assist you with Problems 63–66.

63. Is the speed of the race car after 3 seconds closer to

Speed of a Race Car

160 miles per hour or 190 miles per hour? Speed (in miles per hour)

250

64. After 4 seconds, is the speed of the race car closer to 150 miles per hour or 190 miles per hour?

200 150 100

65. Estimate the speed of the car after 1 second.

50 0 1

2

3

4

5

6

Time (in seconds)

66. Estimate the speed of the car after 6 seconds.

67. Fast Food The following table lists the number of calories consumed by eating some popular fast foods. Use the axes in the figure below to construct a bar chart from the information in the table.

280

McDonald’s Big Mac

510

Burger King Whopper

630

Jack in the Box Colossus Burger

940

Jack in the Box Colossus Burger

Jack in the Box Hamburger

Burger King Whopper

260

McDonald’s Big Mac

270

Burger King Hamburger

Jack in the Box Hamburger

McDonald’s Hamburger

Burger King Hamburger

Calories

1000 900 800 700 600 500 400 300 200 100 0 McDonald’s Hamburger

Food

Number of calories

CALORIES IN FAST FOOD

68. Exercise The following table lists the number of calories burned in 1 hour of exercise by a person who weighs 150

265

Handball

680

Jazzercise

340

Jogging

680

Skiing

544

300 200 100 0

Activity

Skiing

Bowling

400

Jogging

374

Jazzercise

Bicycling

500

Handball

Calories

600

Bowling

Activity

700

Bicycling

CALORIES BURNED BY A 150-POUND PERSON IN ONE HOUR

Number of calories burned in one hour

pounds. Use the axes in the figure below to construct a bar chart from the information in the table.

Subtraction with Whole Numbers

1.4 Objectives A Understand the notation and

Introduction . . . In business, subtraction is used to calculate profit. Profit is found by subtracting costs from revenue. The following double bar chart shows the costs and revenue of the Baby Steps Shoe Company during one 4-week period. $12,000

Costs

vocabulary of subtraction.

B C D

Subtract whole numbers. Subtraction with borrowing. Solving problems with subtraction.

Revenue $10,500

$10,000 $8,400

$8,000 $6,000

$7,500 $7,000 $6,000

$6,000

$6,300

Examples now playing at

MathTV.com/books

$5,000

$4,000 $2,000 0 Week 1

Week 2

Week 3

Week 4

To find the profit for Week 1, we subtract the costs from the revenue, as follows: Profit  $6,000  $5,000 Profit  $1,000 Subtraction is the opposite operation of addition. If you understand addition and can work simple addition problems quickly and accurately, then subtraction shouldn’t be difficult for you.

A Vocabulary The word difference always indicates subtraction. We can state this in symbols by letting the letters a and b represent numbers.

Definition The difference of two numbers a and b is a  b

Table 1 gives some word statements involving subtraction and their mathematical equivalents written in symbols.

TABLE 1

In English

In Symbols

The difference of 9 and 1 The difference of 1 and 9 The difference of m and 4 The difference of x and y 3 subtracted from 8 2 subtracted from t The difference of 7 and 4 is 3. The difference of 9 and 3 is 6.

91 19 m4 xy 83 t2 743 936

1.4 Subtraction with Whole Numbers

33

34

Chapter 1 Whole Numbers

B The Meaning of Subtraction When we want to subtract 3 from 8, we write 8  3,

8 subtract 3,

or

8 minus 3

The number we are looking for here is the difference between 8 and 3, or the number we add to 3 to get 8. That is: 83?

is the same as

?38

In both cases we are looking for the number we add to 3 to get 8. The number we are looking for is 5. We have two ways to write the same statement.

Subtraction

Addition

835

538

or

For every subtraction problem, there is an equivalent addition problem. Table 2 lists some examples.

TABLE 2

Subtraction

Addition

734 972 10  4  6 15  8  7

because because because because

437 279 6  4  10 7  8  15

To subtract numbers with two or more digits, we align the numbers vertically and subtract in columns.

PRACTICE PROBLEMS 1. Subtract. a. 684  431 b. 7,406  3,405

EXAMPLE 1 SOLUTION

Subtract: 376  241

We write the problem vertically, aligning digits with the same place

value. Then we subtract in columns. 376  241

m888 Subtract the bottom number in each column

from the number above it

135

2. a. Subtract 405 from 6,857. b. Subtract 234 from 345.

EXAMPLE 2 SOLUTION

Subtract 503 from 7,835.

In symbols this statement is equivalent to 7,835  503

To subtract we write 503 below 7,835 and then subtract in columns. 7

,

 7

,

3

,

5

5

,

0

,

3

3

,

3

,

2 532

303

853

707

m8

m88888

m8888888888

m888888888888888

Answers 1. a. 253 b. 4,001 2. a. 6,452 b. 111

,

8

Ones Tens Hundreds Thousands

35

1.4 Subtraction with Whole Numbers As you can see, subtraction problems like the ones in Examples 1 and 2 are fairly simple. We write the problem vertically, lining up the digits with the same place value, and subtract in columns. We always subtract the bottom number from the top number.

C Subtraction with Borrowing Subtraction must involve borrowing when the bottom digit in any column is larger than the digit above it. In one sense, borrowing is the reverse of the carrying we did in addition.

EXAMPLE 3 SOLUTION

Subtract: 92  45

We write the problem vertically with the place values of the digits

showing:

3. Subtract. a. 63  47 b. 532  403

92  9 tens  2 ones  45  4 tens

5 ones

Look at the ones column. We cannot subtract immediately, because 5 is larger than 2. Instead, we borrow 1 ten from the 9 tens in the tens column. We can rewrite the number 92 as

Note

The discussion here shows why borrowing is necessary and how we go about it. To understand borrowing you should pay close attention to this discussion.

9 tens  2 ones 8

m8

8888 8

m88

m

 8 tens  1 ten  2 ones 888 m8  8 tens  12 ones Now we are in a position to subtract. 92  9 tens  2 ones  8 tens  12 ones  45  4 tens

5 ones  4 tens

5 ones

4 tens  7 ones The result is 4 tens  7 ones, which can be written in standard form as 47. Writing the problem out in this way is more trouble than is actually necessary. The shorthand form of the same problem looks like this: 8

12

 2 9  4 5 4

m888888888 This shows we have

borrowed 1 ten to go with the 2 ones

7

m8 m88888

Ones

844

Tens

12  5  7

This shortcut form shows all the necessary work involved in subtraction with borrowing. We will use it from now on.

Answer 3. a. 16 b. 129

36

Chapter 1 Whole Numbers The borrowing that changed 9 tens  2 ones into 8 tens  12 ones can be visualized with money.

= $90

4. a. Find the difference of 656 and 283. b. Find the difference of 3,729 and 1,749.

$2

EXAMPLE 4 SOLUTION

$80

$12

Find the difference of 549 and 187.

In symbols the difference of 549 and 187 is written 549  187

Writing the problem vertically so that the digits with the same place value are aligned, we have 549  187 The top number in the tens column is smaller than the number below it. This means that we will have to borrow from the next larger column. 14 m888888888888888

4

 5

4 

Borrow 1 hundred to go with the 4 tens

9

1

8

7

3

6

2

m8888888888

m88888

m 972

14  8  6

Ones Tens

413

Hundreds

The actual work we did in borrowing looks like this: 5 hundreds  4 tens  9 ones

m8

888

88888

m888

m7

 4 hundreds  1 hundred 84 tens  9 ones

88888

m888

 4 hundreds  14 tens  9 ones

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Which sentence below describes the problem shown in Example 1? a. The difference of 241 and 376 is 135. b. The difference of 376 and 241 is 135. 2. Write a subtraction problem using the number 234 that involves borrowing from the tens column to the ones column. Answers 4. a. 373 b. 1,980

3. Write a subtraction problem using the number 234 in which the answer is 111. 4. Describe how you would subtract the number 56 from the number 93.

1.4 Problem Set

Problem Set 1.4 A Perform the indicated operation. [Examples 1, 2, 4] 1. Subtract 24 from 56.

2. Subtract 71 from 89.

3. Subtract 23 from 45.

4. Subtract 97 from 98.

5. Find the difference of 29 and 19.

6. Find the difference of 37 and 27.

7. Find the difference of 126 and 15.

8. Find the difference of 348 and 32.

B Work each of the following subtraction problems. [Examples 1, 2] 9.

975

10.

 663

13.

9,876

480

11.

 260

14.

 8,765

5,008

904

12.

 501

15.

 3,002

7,976

657  507

16.

 3,432

6,980 

470

C Find the difference in each case. (These problems all involve borrowing.) [Example 3] 17. 52  37

18. 65  48

19. 70  37

20. 90  21

21. 74  69

22. 31  28

23. 51  18

24. 64  58

25. 329  234

26. 518  492

27. 348  196

28. 759  661

29.

30.

31.

32.

932  658

33.

905

34.

 367

37.

4,583  2,973

895  597

804

35.

 238

38.

7,849  2,957

647  159

600

36.

 437

39.

79,040  32,957

842  199

800  342

40.

86,492  78,506

37

38

Chapter 1 Whole Numbers

A Complete the following tables. 41.

43.

First Number a

Second Number b

25 24 23 22

15 16 17 18

First Number a

Second Number b

400 400 225 225

256 144 144 81

The Difference of a and b a–b

The Difference of a and b a–b

42.

First Number a

Second Number b

90 80 70 60

79 69 59 49

First Number a

Second Number b

100 100 25 25

36 64 16 9

The Difference of a and b a–b

44. The Difference of a and b a–b

A Write each of the following expressions in words. Use the word difference in each case. 45. 10  2

46. 9  5

47. a  6

48. 7  x

49. 8  2  6

50. m  1  4

51. What number do you subtract from 8 to get 5?

52. What number do you subtract from 6 to get 0?

53. What number do you subtract from 15 to get 7?

54. What number do you subtract from 21 to get 14?

55. What number do you subtract from 35 to get 12?

56. What number do you subtract from 41 to get 11?

A Write each of the following sentences as mathematical expressions. 57. The difference of 8 and 3

58. The difference of x and 2

59. 9 subtracted from y

60. a subtracted from b

61. The difference of 3 and 2 is 1.

62. The difference of 10 and y is 5.

63. The difference of 37 and 9x is 10.

64. The difference of 3x and 2y is 15.

65. The difference of 2y and 15x is 24.

66. The difference of 25x and 9y is 16.

67. The difference of (x  2) and

68. The difference of (x  2) and

(x  1) is 1.

(x  4) is 2.

1.4 Problem Set

D

39

Applying the Concepts

Not all of the following application problems involve only subtraction. Some involve addition as well. Be sure to read each problem carefully.

69. Checkbook Balance Diane has $504 in her checking

70. Checkbook Balance Larry has $763 in his checking

account. If she writes five checks for a total of $249,

account. If he writes a check for each of the three bills

how much does she have left in her account?

listed below, how much will he have left in his account?

71. Home Prices In 1985, Mr. Hicks paid $137,500 for his

Item

Amount

Rent Phone Car repair

$418 25 117

72. Oil Spills In March 1977, an oil tanker hit a reef off

home. He sold it in 2008 for $310,000. What is the

Taiwan and spilled 3,134,500 gallons of oil. In March

difference between what he sold it for and what he

1989, an oil tanker hit a reef off Alaska and spilled

bought it for?

10,080,000 gallons of oil. How much more oil was spilled in the 1989 disaster?

73. Wind Speeds On April 12, 1934, the wind speed on top of

74. Concert Attendance Eleven thousand, seven hundred fifty-

Mount Washington was recorded at 231 miles per hour.

two people attended a recent concert at the Pepsi

When Hurricane Katrina struck on August 28, 2005, the

Arena in Albany, New York. If the arena holds 17,500

highest recorded wind speed was 140 miles per hour.

people, how many empty seats were there at the

How much faster was the wind on top of Mount

concert?

Washington, than the winds from Hurricane Katrina?

40

Chapter 1 Whole Numbers

75. Computer Hard Drive You purchase a new computer with

76. State Size Alaska is the largest state in the United States

320 gigabytes of hard drive capacity. (A gigabyte is

with an area of 663,267 square miles. Rhode Island is

roughly a billion bytes). After loading a variety of

the smallest state with an area of 1,545 square miles.

programs you discover that you have used 147

How many more square miles does Alaska have when

gigabytes of your hard drive’s capacity. How much hard

compared to Rhode Island?

drive capacity do you still have available?

77. Wind Energy The bar chart below shows the states producing the most wind energy in 2006.

78. Auto Insurance Costs The bar chart below shows the cities with the highest annual insurance rates in 2006.

Priciest Cities for Auto Insurance

Wind Energy Texas

Detroit

2,768 MW

California

2,361 MW

$5,894

Philadelphia

$4,440

Newark, N.J.

Iowa

936 MW

Los Angeles

Minnesota

895 MW

New York City

$3,977 $3,430 $3,303 0

Washington

$2000

$3000

$4000

$5000

$6000

818 MW Source: American Wind Energy Association 2006

a. Use the information in the bar chart to fill in the missing entries in the table.

State

$1000

Energy (megawatts)

Texas California Iowa

Source: Runzheimer International

a. Use the information in the bar chart to fill in the missing entries in the table.

City

Cost (dollars)

Detroit Philadelphia Los Angeles 818

b. How much more wind energy is produced in Texas than in California?

3,303

b. How much more does auto insurance cost in Detroit than in Los Angeles?

Multiplication with Whole Numbers Introduction . . . A supermarket orders 35 cases of a certain soft drink. If each case contains 12

1.5 Objectives A Multiply whole numbers. B Understand the notation and vocabulary of multiplication.

cans of the drink, how many cans were ordered?

C D E

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

Identify properties of multiplication. Solve equations with multiplication. Solve applications with multiplication.

12 cans

12 cans

Examples now playing at

12 cans

MathTV.com/books

12 cans

12 cans

12 cans

12 cans

To solve this problem and others like it, we must use multiplication. Multiplication is what we will cover in this section.

A Multiplying Whole Numbers To begin, we can think of multiplication as shorthand for repeated addition. That is, multiplying 3 times 4 can be thought of this way: 3 times 4  4  4  4  12 Multiplying 3 times 4 means to add three 4’s. We can write 3 times 4 as 3  4, or 3  4.

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

Multiply: 3  4,000

Using the definition of multiplication as repeated addition, we have

1. Multiply. a. 4  70 b. 4  700 c. 4  7,000

3  4,000  4,000  4,000  4,000  12,000 Here is one way to visualize this process.

+ $4,000

+ $4,000

= $4,000

$12,000

Notice that if we had multiplied 3 and 4 to get 12 and then attached three zeros on the right, the result would have been the same.

1.5 Multiplication with Whole Numbers

Answer 1. a. 280 b. 2,800 c. 28,000

41

42

Chapter 1 Whole Numbers

Note

B Notation

The kind of notation we will use to indicate multiplication will depend on the situation. For example, when we are solving equations that involve letters, it is not a good idea to indicate multiplication with the symbol , since it could be confused with the letter x. The symbol we will use to indicate multiplication most often in this book is the multiplication dot.

There are many ways to indicate multiplication. All the following statements are equivalent. They all indicate multiplication with the numbers 3 and 4. 3  4,

3  4,

3(4),

(3)4,

(3)(4),

4 3

If one or both of the numbers we are multiplying are represented by letters, we may also use the following notation:

Note

5n

means

5 times n

ab

means

a times b

B Vocabulary

We are assuming that you know the basic multiplication facts given in the table below. If you need some practice with these facts, go to Appendix C at the back of the book.

We use the word product to indicate multiplication. If we say “The product of 3 and 4 is 12,” then we mean 3  4  12 Both 3  4 and 12 are called the product of 3 and 4. The 3 and 4 are called factors.

BASIC MULTIPLICATION FACTS  1 2

3

4

5

6

7

8

9

1

1

2

3

4

5

6

7

8

9

2

2

4

6

8 10 12 14 16 18

3

3

6

9 12 15 18 21 24 27

4

4

8 12 16 20 24 28 32 36

5

5 10 15 20 25 30 35 40 45

6

6 12 18 24 30 36 42 48 54

7

7 14 21 28 35 42 49 56 63

8

8 16 24 32 40 48 56 64 72

9

9 18 27 36 45 54 63 72 81

TABLE 1

In English The The The The The The

product product product product product product

EXAMPLE 2

of of of of of of

2 and 5 5 and 2 4 and n x and y 9 and 6 is 54 2 and 8 is 16

In Symbols 25 52 4n xy 9  6  54 2  8  16

Identify the products and factors in the statement

9  8  72 2. Identify the products and factors in the statement 6  7  42

3. Identify the products and

SOLUTION

The factors are 9 and 8, and the products are 9  8 and 72.

EXAMPLE 3

factors in the statement 70  2  5  7

Identify the products and factors in the statement

30  2  3  5

SOLUTION

The factors are 2, 3, and 5. The products are 2  3  5 and 30.

C Distributive Property To develop an efficient method of multiplication, we need to use what is called the distributive property. To begin, consider the following two problems:

Answers 2. Factors: 6, 7; products: 6  7 and 42 3. Factors: 2, 5, 7; products: 2  5  7 and 70

Problem 1

Problem 2

3(4  5)

3(4)  3(5)

 3(9)

 12  15

 27

 27

The result in both cases is the same number, 27. This indicates that the original two expressions must have been equal also. That is, 3(4  5)  3(4)  3(5)

43

1.5 Multiplication with Whole Numbers This is an example of the distributive property. We say that multiplication distributes over addition. 3(4  5)  3(4)  3(5)

4

4+5

=

3 times

+

3 times

=

3(4 + 5)

5

3 times

+

3•4

3•5

We can write this property in symbols using the letters a, b, and c to represent any three whole numbers.

Distributive Property If a, b, and c represent any three whole numbers, then a(b  c)  a(b)  a(c)

A Multiplication with Whole Numbers, and Area Suppose we want to find the product 7(65). By writing 65 as 60  5 and applying the distributive property, we have: 7(65)  7(60  5)  7(60)  7(5)  420  35  455

65  60  5 Distributive property Multiplication Addition

We can write the same problem vertically like this: 60  5 

7 35 m



420 m

7(5)  35 7(60)  420

455 This saves some space in writing. But notice that we can cut down on the amount of writing even more if we write the problem this way: 3

STEP 2: 7(6)  42; add the 8n 65 3 we carried to 42 to get 45 8 88n  7

STEP 1: 7(5)  35; write the 5 in the ones column, and then carry the 3 to the tens column

455 m888888888888888

This shortcut notation takes some practice.

EXAMPLE 4

Multiply: 9(43) 2

STEP 2: 9(4)  36; add the 8n 43 2 we carried to 36 to get 38 8 88  9 n

STEP 1: 9(3)  27; write the 7 in the ones column, and then carry the 2 to the tens column

4. Multiply. a. 8(57) b. 8(570)

387 m88888888888888

Answer 4. a. 456 b. 4,560

44

5. Multiply. a. 45(62) b. 45(620)

Chapter 1 Whole Numbers

EXAMPLE 5 SOLUTION

Multiply: 52(37)

This is the same as 52(30  7) or by the distributive property 52(30)  52(7)

We can find each of these products by using the shortcut method: 1

52

Note

This discussion is to show why we multiply the way we do. You should go over it in detail, so you will understand the reasons behind the process of multiplication. Besides being able to do multiplication, you should understand it.

52

 30

7

1,560

364

The sum of these two numbers is 1,560  364  1,924. Here is a summary of what we have so far:

37  30  7 Distributive property Multiplication Addition

52(37)  52(30  7)  52(30)  52(7)  1,560  364  1,924 The shortcut form for this problem is 52  37

m88888 7(52)  364

364  1,560

m888

30(52)  1,560

1,924 In this case we have not shown any of the numbers we carried, simply because it becomes very messy.

6. Multiply. a. 356(641) b. 3,560(641)

EXAMPLE 6 SOLUTION

Multiply: 279(428) 279

  428 2,232

m888888 8(279)  2,232

5,580

m88888 20(279)  5,580

 111,600

400(279)  111,600

m888

119,412

USING

TECHNOLOGY

Calculators Here is how we would work the problem shown in Example 6 on a calculator: Scientific Calculator: 279 Graphing Calculator: 279

 

428 428

 ENT

Estimating One way to estimate the answer to the problem shown in Example 6 is to round each number to the nearest hundred and then multiply the rounded numbers. Doing so would give us this: 300(400)  120,000 Answers 5. a. 2,790 b. 27,900 6. a. 228,196 b. 2,281,960

Our estimate of the answer is 120,000, which is close to the actual answer, 119,412. Making estimates is important when we are using calculators; having an estimate of the answer will keep us from making major errors in multiplication.

45

1.5 Multiplication with Whole Numbers

E Applications EXAMPLE 7

7. If each tablet of vitamin C

A supermarket orders

12 cans

35 cases of a certain soft drink. If each case contains 12 cans of the drink, how many cans were ordered?

12 cans

12 cans

12 cans

SOLUTION

We have 35 cases, and each case

has 12 cans. The total number of cans is the

12 cans

12 cans

12 cans

product of 35 and 12, which is 35(12): 12  35 60  360

12 cans

12 cans

12 cans

12 cans

12 cans

5(12)  60 m888888 30(12)  360 m888888

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

contains 550 milligrams of vitamin C, what is the total number of milligrams of vitamin C in a bottle that contains 365 tablets?

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

12 cans

420 There is a total of 420 cans of the soft drink.

EXAMPLE 8

Shirley earns $12 an hour for the first 40 hours she works

each week. If she has $109 deducted from her weekly check for taxes and retirement, how much money will she take home if she works 38 hours this week?

SOLUTION

8. If Shirley works 36 hours the next week and has the same amount deducted from her check for taxes and retirement, how much will she take home?

To find the amount of money she earned for the week, we multiply

12 and 38. From that total we subtract 109. The result is her take-home pay. Without showing all the work involved in the calculations, here is the solution: 38($12)  $456 $456  $109  $347

EXAMPLE 9

Her total weekly earnings Her take-home pay

In 1993, the gov-

ernment standardized the way in which

9. The amounts given in the

Nutrition Facts

nutrition information is presented on the

Serving Size 1 oz. (28g/About 32 chips) Servings Per Container: 3

labels of most packaged food products.

Amount Per Serving

Figure 1 shows one of these standardized

Calories 160

Calories from fat 90

food labels. It is from a package of Fritos

% Daily Value* 16%

Corn Chips that I ate the day I was writing

Total Fat 10 g

this example. Approximately how many

Saturated Fat 1.5g Cholesterol 0mg

8%

Sodium 160mg

7%

Total Carbohydrate 15g Dietary Fiber 1g

5%

chips are in the bag, and what is the total number of calories consumed if all the chips in the bag are eaten?

SOLUTION

Reading toward the top of

the label, we see that there are about 32 chips in one serving, and 3 servings in the bag. Therefore, the total number of chips in the bag is 3(32)  96 chips

0%

4%

Sugars 0g Protein 2g Vitamin A 0% Calcium 2%

• •

Vitamin C 0% Iron 0%

middle of the nutrition label in Figure 1 are for one serving of chips. If all the chips in the bag are eaten, how much fat has been consumed? How much sodium?

Note

The letter g that is shown after some of the numbers in the nutrition label in Figure 1 stands for grams, a unit used to measure weight. The unit mg stands for milligrams, another, smaller unit of weight. We will have more to say about these units later in the book.

*Percent Daily Values are based on a 2,000 calorie diet

FIGURE 1 Answers 7. 200,750 milligrams 8. $323

46

Chapter 1 Whole Numbers This is an approximate number, because each serving is approximately 32 chips. Reading further we find that each serving contains 160 calories. Therefore, the total number of calories consumed by eating all the chips in the bag is 3(160)  480 calories As we progress through the book, we will study more of the information in nutrition labels.

10. If a 150-pound person bowls for 3 hours, will he or she burn all the calories consumed by eating two bags of the chips mentioned in Example 9?

EXAMPLE 10

The table below lists the number of calories burned in 1

hour of exercise by a person who weighs 150 pounds. Suppose a 150-pound person goes bowling for 2 hours after having eaten the bag of chips mentioned in Example 9. Will he or she burn all the calories consumed from the chips?

Calories Burned in 1 Hour by a 150-Pound Person

Activity Bicycling Bowling Handball Jazzercize Jogging Skiing

SOLUTION

374 265 680 340 680 544

Each hour of bowling burns 265 calories. If the person bowls for 2

hours, a total of 2(265)  530 calories will have been burned. Because the bag of chips contained only 480 calories, all of them have been burned with 2 hours of bowling.

C More Properties of Multiplication Multiplication Property of 0 If a represents any number, then a00

and

0a0

In words: Multiplication by 0 always results in 0.

Multiplication Property of 1 If a represents any number, then a1a

and

1aa

In words: Multiplying any number by 1 leaves that number unchanged.

Commutative Property of Multiplication If a and b are any two numbers, then ab  ba Answers 9. 30 g of fat, 480 mg of sodium 10. No

In words: The order of the numbers in a product doesn’t affect the result.

47

1.5 Multiplication with Whole Numbers

Associative Property of Multiplication If a, b, and c represent any three numbers, then (ab)c  a(bc) In words: We can change the grouping of the numbers in a product without changing the result.

To visualize the commutative property, we can think of an instructor with 12 students.

=

4 chairs across, 3 chairs back

EXAMPLE 11

3 chairs across, 4 chairs back

Use the commutative property of multiplication to rewrite

of multiplication to rewrite each of the following products. a. 5  8 b. 7(2)

each of the following products: a. 7  9

SOLUTION

b. 4(6)

Applying the commutative property to each expression, we have: a. 7  9  9  7

EXAMPLE 12

b. 4(6)  6(4)

Use the associative property of multiplication to rewrite

each of the following products: a. (2  7)  9

SOLUTION

11. Use the commutative property

b. 3  (8  2)

Applying the associative property of multiplication, we regroup as

12. Use the associative property of multiplication to rewrite each of the following products. a. (5  7)  4 b. 4  (6  4)

follows: a. (2  7)  9  2  (7  9)

b. 3  (8  2)  (3  8)  2

D Solving Equations If n is used to represent a number, then the equation 4  n  12 is read “4 times n is 12,” or “The product of 4 and n is 12.” This means that we are looking for the number we multiply by 4 to get 12. The number is 3. Because the equation becomes a true statement if n is 3, we say that 3 is the solution to the 13. Use multiplication facts to find

equation.

EXAMPLE 13

Find the solution to each of the following equations:

a. 6  n  24

SOLUTION

b. 4  n  36

c. 15  3  n

d. 21  3  n

a. The solution to 6  n  24 is 4, because 6  4  24. b. The solution to 4  n  36 is 9, because 4  9  36. c. The solution to 15  3  n is 5, because 15  3  5. d. The solution to 21  3  n is 7, because 21  3  7.

the solution to each of the following equations. a. 5  n  35 b. 8  n  72 c. 49  7  n d. 27  9  n

Answers 11. a. 8  5 b. 2(7) 12. a. 5  (7  4) b. (4  6)  4 13. a. 7 b. 9 c. 7 d. 3

48

Chapter 1 Whole Numbers

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Use the numbers 7, 8, and 9 to give an example of the distributive property. 2. When we write the distributive property in words, we say “multiplication distributes over addition.” It is also true that multiplication distributes over subtraction. Use the letters a, b, and c to write the distributive property using multiplication and subtraction. 3. We can multiply 8 and 487 by writing 487 in expanded form as 400  80  7 and then applying the distributive property. Apply the distributive property to the expression below and then simplify. 8(400  80  7)  4. Find the mistake in the following multiplication problem. Then work the problem correctly. 43  68 344  258 602

1.5 Problem Set

Problem Set 1.5 A Multiply each of the following. [Example 1] 1. 3  100

2. 7  100

3. 3  200

7. 5  1,000

8. 8  1,000

9. 3  7,000

4. 4  200

5. 6  500

6. 8  400

10. 6  7,000

11. 9  9,000

12. 7  7,000

A Find each of the following products. (Multiply.) In each case use the shortcut method. [Examples 4–6] 13. 25

14. 43

15. 38

4

9

6

19.

72

20.

 20

25.

11  11

68

21.

 30

26.

12  21

19

16.

22.

 50

27.

97  16

28.

45

17. 18

18. 29

 7

2

3

24

23.

69

24.

27

 40

 25

 36

24

29. 168

30. 452

 39

 25

 34

49

50

Chapter 1 Whole Numbers

31. 728

32. 680

 91

 76

37.

532

38.

 200

43.

2,468 

135

33.

34.

 400

277  900

44.

698

2,725  324

39.

856



35.

 600

40.

 232

45. 24,563

879

455

46.

56,728 

36.

 111

41.

 248

735

111

976

 321

42.

 628

47.

44,777

852

 5,888

First Number a

Second Number b

25 25 50 50

15 30 15 30

First Number a

Second Number b

11 11 22 22

111 222 111 222

First Number a

Second Number b

10 100 1,000 10,000

12 12 12 12

123

432  555

48.

33,999 

2,555

B Complete the following tables. 49.

First Number a

Second Number b

11 11 22 22

11 22 22 44

First Number a

Second Number b

25 25 25 25

10 100 1,000 10,000

First Number a

Second Number b

12 36 12 36

20 20 40 40

Their Product ab

50.

52.

51. Their Product ab

Their Product ab

Their Product ab

54.

53. Their Product ab

Their Product ab

1.5 Problem Set

B Write each of the following expressions in words, using the word product. 55. 6  7

56. 9(4)

57. 2  n

58. 5  x

59. 9  7  63

60. (5)(6)  30

B Write each of the following in symbols. 61. The product of 7 and n

62. The product of 9 and x

63. The product of 6 and 7 is 42.

64. The product of 8 and 9 is 72.

65. The product of 0 and 6 is 0.

66. The product of 1 and 6 is 6.

B Identify the products in each statement. 67. 9  7  63

68. 2(6)  12

69. 4(4)  16

70. 5  5  25

73. 12  2  2  3

74. 42  2  3  7

B Identify the factors in each statement. 71. 2  3  4  24

72. 6  1  5  30

C Rewrite each of the following using the commutative property of multiplication. [Example 11] 75. 5(9)

76. 4(3)

77. 6  7

78. 8  3

C Rewrite each of the following using the associative property of multiplication. [Example 12] 79. 2  (7  6)

80. 4  (8  5)

81. 3  (9  1)

82. 5  (8  2)

51

52

Chapter 1 Whole Numbers

C Use the distributive property to rewrite each expression, then simplify. 83. 7(2  3)

84. 4(5  8)

85. 9(4  7)

86. 6(9  5)

87. 3(x  1)

88. 5(x  8)

89. 2(x  5)

90. 4(x  3)

93. 9  n  81

94. 6  n  36

D Find a solution for each equation. [Example 13] 91. 4  n  12

92. 3  n  12

95. 0  n  5

96. 6  1  n

E

Applying the Concepts

Most, but not all, of the application problems that follow require multiplication. Read the problems carefully before trying to solve them.

97. Planning a Trip A family decides to drive their compact car on their vacation. They figure it will require a total

98. Rent A student pays $675 rent each month. How much money does she spend on rent in 2 years?

of about 130 gallons of gas for the vacation. If each gallon of gas will take them 22 miles, how long is the trip they are planning?

1 GAL./ 22 MI.

1 GAL./ 22 MI.

RENT ENT RENT R ER NT DUE JAN. 1 RENT R E NT DUE JAN. RENT R EDUE NTJAN. 1 1 RENT R E NT DUE JAN. 1 RENT EDUE NT JAN. 1 RENT R ER NT DUE JAN. 1 RENT R E NT DUE JAN. 1 RENT R E NT DUE JAN. 1 RENT EDUE NT JAN. 1 RENT RNT ER NT DUE JAN. 1 RENT RE E DUE JAN. 1 RENT DUE JAN. 1 DUE JAN. 1

$675

53

1.5 Problem Set 99. Downloading Songs You receive a gift card for the

100. Cost of Building a Home When you consider building a

Apple™ iTunes™ store for $25.00 and download 18

new home it is helpful to be able to estimate the cost

songs at $0.99 per song. How much is left on your gift

of building that house. A simple way to do this is to

card?

multiply the number of square feet under the roof of the house by the average building cost per square foot. Suppose you contact a builder who estimates that, on average, he charges $142.00 per square foot. Determine the cost to build a 2,067 square foot house.

101. World’s Busiest Airport Atlanta, Georgia is home to the

102. Flowers It is probably no surprise that Valentine’s Day

world's busiest airport, Hartsfield-Jackson Atlanta

is the busiest day of the year for florists. It is estimated

International Airport. According to the Federal

that 214 million roses were produced for Valentine’s

Aviation Administration about 50 jets can land and

Day in 2007 (Source: Society of American Florists). If a

take off every 15 minutes which is about 200 jets an

single rose costs a consumer $2.50, what was the total

hour. About how many jets land and take off in the

revenue for the roses produced?

month of July?

Exercise and Calories The table below is an extension of the table we used in Example 10 of this section. It gives the amount of energy expended during 1 hour of

Nutrition Facts

various activities for people of different weights. The accompanying figure is a

Serving Size 1 oz. (28g/About 12 chips) Servings Per Container About 2

nutrition label from a bag of Doritos tortilla chips. Use the information from the

Amount Per Serving

table and the nutrition label to answer Problems 103–108.

Calories 140

Calories from fat 60 % Daily Value* 11%

Total Fat 7g

CALORIES BURNED THROUGH EXERCISE Activity

Saturated Fat 1g Cholesterol 0mg

6%

Sodium 170mg

7% 6%

0%

120 Pounds

Calories Per Hour 150 Pounds

180 Pounds

Total Carbohydrate 18g Dietary Fiber 1g

299 212 544 272 544 435

374 265 680 340 680 544

449 318 816 408 816 653

Sugars less than 1g

Bicycling Bowling Handball Jazzercise Jogging Skiing

103. Suppose you weigh 180 pounds. How many calories would you burn if you play handball for 2 hours and

4%

Protein 2g Vitamin A 0% Calcium 4%

• •

Vitamin C 0% Iron 2%

*Percent Daily Values are based on a 2,000 calorie diet

104. How many calories are burned by a 120-lb person who jogs for 1 hour and then goes bike riding for 2 hours?

then ride your bicycle for 1 hour?

105. How many calories would you consume if you ate the

106. Approximately how many chips are in the bag?

entire bag of chips?

107. If you weigh 180 pounds, will you burn off the calories

108. If you weigh 120 pounds, will you burn off the calories

consumed by eating 3 servings of tortilla chips if you

consumed by eating 3 servings of tortilla chips if you

ride your bike 1 hour?

ride your bike for 1 hour?

54

Chapter 1 Whole Numbers

Estimating Mentally estimate the answer to each of the following problems by rounding each number to the indicated place and then multiplying.

109.

750 hundred

110.

 12 ten

113.

2,399 

thousand

114.

591

hundred

 323

hundred

9,999  666

698 hundred

111.

3,472 

511

thousand hundred

112.

399

hundred

 298

hundred

thousand hundred

Extending the Concepts: Number Sequences A geometric sequence is a sequence of numbers in which each number is obtained from the previous number by multiplying by the same number each time. For example, the sequence 3, 6, 12, 24, . . . is a geometric sequence, starting with 3, in which each number comes from multiplying the previous number by 2. Find the next number in each of the following geometric sequences.

115. 5, 10, 20, . . .

116. 10, 50, 250, . . .

117. 2, 6, 18, . . .

118. 12, 24, 48, . . .

Division with Whole Numbers

1.6 Objectives A Understand the notation and

Introduction . . . Darlene is planning a party and would like to serve 8-ounce glasses of soda. The glasses will be filled from 32-ounce bottles of soda. In order to know how many bottles of soda to buy, she needs to find out how many of the 8-ounce glasses can

vocabulary of division.

B C

Divide whole numbers. Solve applications using division.

be filled by one of the 32-ounce bottles. One way to solve this problem is with division: dividing 32 by 8. A diagram of the problem is shown in Figure 1.

Examples now playing at

MathTV.com/books

8-ounce glasses

32-ounce bottle

FIGURE 1

As a division problem:

As a multiplication problem:

32  8  4

4  8  32

A Notation As was the case with multiplication, there are many ways to indicate division. All the following statements are equivalent. They all mean 10 divided by 5. 10  5,

10 , 5

10/5,

51 0 

The kind of notation we use to write division problems will depend on the 0  mostly with the long-division problems situation. We will use the notation 51 10

found in this chapter. The notation 5 will be used in the chapter on fractions and in later chapters. The horizontal line used with the notation

10  5

is called the

fraction bar.

A Vocabulary The word quotient is used to indicate division. If we say “The quotient of 10 and 5 is 2,” then we mean 10  5  2

or

10   2 5

The 10 is called the dividend, and the 5 is called the divisor. All the expressions, 10

10  5, 5, and 2, are called the quotient of 10 and 5.

1.6 Division with Whole Numbers

55

56

Chapter 1 Whole Numbers

TABLE 1

In English

In Symbols

The quotient of 15 and 3

15 15  3, or , or 15/3 3

The quotient of 3 and 15

3 3  15, or , or 3/15 15

The quotient of 8 and n

8 8  n, or , or 8/n n

x divided by 2

x x  2, or , or x/2 2

The quotient of 21 and 3 is 7.

21 21  3  7, or   7 3

The Meaning of Division One way to arrive at an answer to a division problem is by thinking in terms of multiplication. For example, if we want to find the quotient of 32 and 8, we may ask, “What do we multiply by 8 to get 32?” 32  8  ?

8  ?  32

means

Because we know from our work with multiplication that 8  4  32, it must be true that 32  8  4 Table 2 lists some additional examples.

TABLE 2

Division

Multiplication

18  6  3

because

6  3  18

32  8  4

because

8  4  32

10  2  5

because

2  5  10

72  9  8

because

9  8  72

B Division by One-Digit Numbers Consider the following division problem: 465  5 We can think of this problem as asking the question, “How many fives can we subtract from 465?” To answer the question we begin subtracting multiples of 5. One way to organize this process is shown below: 90

m88 We first guess that there are at least 90 fives in 465

54  6 5  450 15

m88 90(5)  450 m88 15 is left after we subtract 90 fives from 465

What we have done so far is subtract 90 fives from 465 and found that 15 is still left. Because there are 3 fives in 15, we continue the process.

57

1.6 Division with Whole Numbers 3

m88 There are 3 fives in 15

90 6 5  54 450 15  15 0

m88 3  5  15 m88 The difference is 0

The total number of fives we have subtracted from 465 is 90  3  93 We now summarize the results of our work. 465  5  93

1

which we check

93

with multiplication 8n  5 465

A Notation The division problem just shown can be shortened by eliminating the subtraction signs, eliminating the zeros in each estimate, and eliminating some of the numbers that are repeated in the problem. 3 90 54 6 5  450

93

looks like this.

54 6 5 

m78

The shorthand form for this problem

45

15

15

15

15

0

0

The arrow indicates that we bring down the 5 after we subtract.

The problem shown above on the right is the shortcut form of what is called long division. Here is an example showing this shortcut form of long division from start to finish.

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

Divide: 595  7

Because 7(8)  56, our first estimate of the number of sevens that

1. Divide. a. 296  4 b. 2,960  4

can be subtracted from 595 is 80: 8

m88 The 8 is placed above the tens column

so we know our first estimate is 80

m78

75 9 5 

m88 8(7)  56

35

m88 59  56  3; then bring down the 5

56

Since 7(5)  35, we have 85

m88 There are 5 sevens in 35

m78

75 9 5  56

35 35 0

m88 5(7)  35 m88 35  35  0

Our result is 595  7  85, which we can check with multiplication: 3

85 7 595

Answer 1. a. 74 b. 740

58

Chapter 1 Whole Numbers

B Division by Two-Digit Numbers 2. Divide. a. 6,792  24 b. 67,920  24

EXAMPLE 2 SOLUTION

Divide: 9,380  35

In this case our divisor, 35, is a two-digit number. The process of

division is the same. We still want to find the number of thirty-fives we can subtract from 9,380. m88 The 2 is placed above the hundreds column

2 m78

359 ,3 8 0  70

m88 2(35)  70

2 38

m88 93  70  23; then bring down the 8

We can make a few preliminary calculations to help estimate how many thirtyfives are in 238: 5  35  175

6  35  210

7  35  245

Because 210 is the closest to 238 without being larger than 238, we use 6 as our next estimate: 26

m88 6 in the tens column means this estimate is 60

70

m8888888

359 ,3 8 0  2 38

2 10

m88 6(35)  210

280 m88 238  210  28; bring down the 0 Because 35(8)  280, we have 268 ,3 8 0  359 70 2 38 2 10 280 280 m88 8(35)  280 0 m88 280  280  0 We can check our result with multiplication: 268  35 1,340 8,040 9,380

3. Divide.

EXAMPLE 3

Divide: 1,872 by 18.

1,872  9

SOLUTION

Here is the first step. 1

m88 1 is placed above hundred column

181 ,8 7 2  18 0 Answer 2. a. 283 b. 2,830

m88 Multiply 1(18) to get 18 m88 Subtract to get 0

59

1.6 Division with Whole Numbers The next step is to bring down the 7 and divide again. 10

m88 0 is placed above tens column. 0 is the largest number

181 ,8 7 2  m78

we can multiply by 18 and not go over 7

18

07 0

m88 Multiply 0(18) to get 0

7

m88 Subtract to get 7

Here is the complete problem. 104 18

m8888888

m78

,8 7 2  181 07 0

72 72 0 To show our answer is correct, we multiply. 18(104)  1,872

B Division with Remainders Suppose Darlene was planning to use 6-ounce glasses instead of 8-ounce glasses for her party. To see how many glasses she could fill from the 32-ounce bottle, she would divide 32 by 6. If she did so, she would find that she could fill 5 glasses, but after doing so she would have 2 ounces of soda left in the bottle. A diagram of this problem is shown in Figure 2.

2 ounces left in bottle

32-ounce bottle

6-ounce glasses 30 ounces total

FIGURE 2 Writing the results in the diagram as a division problem looks like this: 5 m88 Quotient Divisor 88n 63 2  m88 Dividend 30 2 m88 Remainder

3. 208

60

4. Divide. a. 1,883  27 b. 1,883  18

Chapter 1 Whole Numbers

EXAMPLE 4 SOLUTION

Divide: 1,690  67

Dividing as we have previously, we get 25 m78

,6 9 0  671 1 34

350 335 15 m88 15 is left over

subtracted. In a situation like this we call 15 the remainder and write

15

25 R 15

2567

m78

or

671 ,6 9 0 

m78

671 ,6 9 0 

SCIENTIFIC CALCULATOR:

1 34

1690  67 

GRAPHING CALCULATOR: 1690  67 ENT In both cases the calculator will display 25.223881 (give or take a few digits at the end), which gives the remainder in decimal form. We will discuss decimals later in the book.

m

8

These indicate that the remainder is 15 8

Here is how we would work the problem shown in Example 4 on a calculator:

We have 15 left, and because 15 is less than 67, no more sixty-sevens can be

m

CALCULATOR NOTE

1 34

350

350

335

335

15

15

Both forms of notation shown above indicate that 15 is the remainder. The 15 notation R 15 is the notation we will use in this chapter. The notation  will be 67 useful in the chapter on fractions. To check a problem like this, we multiply the divisor and the quotient as usual, and then add the remainder to this result: 67  25 335 1,340 1,675 m88 Product of divisor and quotient m8888

1,675  15  1,690 m

Remainder

5. A family spends $1,872 on a 12-

Note

To estimate the answer to Example 5 quickly, we can replace 35,880 with 36,000 and mentally calculate 36,000  12 which gives an estimate of 3,000. Our actual answer, 2,990, is close enough to our estimate to convince us that we have not made a major error in our calculation.

Answers 4. a. 69 R 20, or 692207 b. 104 R 11, or 1041118 5. $156

88

Dividend

C Applications EXAMPLE 5

A family has an annual income of $35,880. How much is

their average monthly income?

SOLUTION

Because there are 12 months in a year and the yearly (annual)

income is $35,880, we want to know what $35,880 divided into 12 equal parts is. Therefore we have 2 990 5 ,8 8 0  123

m888 m888888888 m8888888888888888

day vacation. How much did they spend each day on average?

88

24  11 8

10 8  1 08

1 08 00

Because 35,880  12  2,990, the monthly income for this family is $2,990.

1.6 Division with Whole Numbers

Division by Zero We cannot divide by 0. That is, we cannot use 0 as a divisor in any division problem. Here’s why. Suppose there was an answer to the problem 8   ? 0 That would mean that 0?8 But we already know that multiplication by 0 always produces 0. There is no number we can use for the ? to make a true statement out of 0?8 Because this was equivalent to the original division problem 8   ? 0 8 we have no number to associate with the expression 0. It is undefined.

Rule Division by 0 is undefined. Any expression with a divisor of 0 is undefined. We cannot divide by 0.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Which sentence below describes the problem shown in Example 1? a. The quotient of 7 and 595 is 85. b. Seven divided by 595 is 85. c. The quotient of 595 and 7 is 85. 2. In Example 2, we divide 9,380 by 35 to obtain 268. Suppose we add 35 to 9,380, making it 9,415. What will our answer be if we divide 9,415 by 35? 3. Example 4 shows that 1,690  67 gives a quotient of 25 with a remainder of 15. If we were to divide 1,692 by 67, what would the remainder be? 4. Explain why division by 0 is undefined in mathematics.

61

This page intentionally left blank

1.6 Problem Set

Problem Set 1.6 A Write each of the following in symbols. 1. The quotient of 6 and 3

2. The quotient of 3 and 6

3. The quotient of 45 and 9

4. The quotient of 12 and 4

5. The quotient of r and s

6. The quotient of s and r

7. The quotient of 20 and 4 is 5.

8. The quotient of 20 and 5 is 4.

Write a multiplication statement that is equivalent to each of the following division statements.

9. 6  2  3

48 6

13.   8

10. 6  3  2

35 7

14.   5

36 9

36 4

11.   4

12.   9

15. 28  7  4

16. 81  9  9

B Find each of the following quotients. (Divide.) [Examples 1–3] 17. 25  5

18. 72  8

19. 40  5

20. 12  2

21. 9  0

22. 7  1

23. 360  8

24. 285  5

25. 

26. 

267 3

27. 57 ,6 5 0 

28. 55 ,6 7 0 

29. 56 ,7 5 0 

30. 56 ,5 7 0 

31. 35 4 ,0 0 0 

32. 35 0 ,4 0 0 

33. 35 0 ,0 4 0 

34. 35 0 ,0 0 4 

138 6

63

64

Chapter 1 Whole Numbers

Estimating Work Problems 35 through 38 mentally, without using a calculator.

35. The quotient 845  93 is closest to which of the following numbers?

a. 10

b. 100

following numbers?

c. 1,000

d. 10,000

37. The quotient 15,208  771 is closest to which of the following numbers?

a. 2

b. 20

c. 200

36. The quotient 762  43 is closest to which of the a. 2

b. 20

c. 200

d. 2,000

38. The quotient 24,471  523 is closest to which of the following numbers?

d. 2,000

a. 5

b. 50

c. 500

d. 5,000

Mentally give a one-digit estimate for each of the following quotients. That is, for each quotient, mentally estimate the answer using one of the digits 1, 2, 3, 4, 5, 6, 7, 8, or 9.

39. 316  289

40. 662  289

41. 728  355

42. 728  177

43. 921  243

44. 921  442

45. 673  109

46. 673  218

B Divide. You shouldn’t have any wrong answers because you can always check your results with multiplication. [Examples 1–3] 2,401 49

4,606 49

47. 1,440  32

48. 1,206  67

49. 

50. 

51. 281 2 ,0 9 6 

52. 289 6 ,0 1 2 

53. 639 0 ,5 9 4 

54. 451 7 ,5 9 5 

55. 876 1 ,3 3 5 

56. 794 8 ,0 3 2 

57. 451 3 5 ,9 0 0 

58. 562 2 7 ,9 2 0 

1.6 Problem Set

65

B Complete the following tables. 59.

60. First Number

Second Number

a

b

100 100 100 100

25 26 27 28

The Quotient of a and b a ––– b

First Number

Second Number

a

b

100 101 102 103

25 25 25 25

The Quotient of a and b a ––– b

B The following division problems all have remainders. [Example 4] 61. 63 7 0 

62. 83 9 0 

63. 32 7 1 

64. 31 7 2 

65. 263 4 5 

66. 265 4 3 

67. 711 6 ,6 2 0 

68. 713 3 ,2 4 0 

69. 239 ,2 5 0 

70. 232 0 ,8 0 0 

71. 1695 ,9 5 0 

72. 3913 4 ,4 5 0 

C

Applying the Concepts

[Example 5]

The application problems that follow may involve more than merely division. Some may require addition, subtraction, or multiplication, whereas others may use a combination of two or more operations.

73. Monthly Income A family has an annual income of $42,300. How much is their monthly income?

75. Price per Pound If 6 pounds of a certain kind of fruit cost $4.74, how much does 1 pound cost?

74. Hourly Wages If a man works an 8-hour shift and is paid $96, how much does he make for 1 hour?

76. Cost of a Dress A dress shop orders 45 dresses for a total of $2,205. If they paid the same amount for each dress, how much was each dress?

66

Chapter 1 Whole Numbers

77. Filling Glasses How many 32-ounce bottles of Coke will be needed to fill sixteen 6-ounce glasses?

78. Filling Glasses How many 8-ounce glasses can be filled from three 32-ounce bottles of soda?

soda sodapop soda pop pop

three 32-ounce bottles = ______ 8-ounce glasses

79. Filling Glasses How many 5-ounce glasses can be filled

80. Filling Glasses How many 3-ounce glasses can be filled

from a 32-ounce bottle of milk? How many ounces of

from a 28-ounce bottle of milk? How many ounces of

milk will be left in the bottle when all the glasses are

milk will be left in the bottle when all the glasses are

full?

filled?

81. Boston Red Sox The annual payroll for the Boston Red

82. Miles per Gallon A traveling salesman kept track of his

Sox for the 2007 season was about $156 million

mileage for 1 month. He found that he traveled 1,104

dollars. If there are 40 players on the roster what is the

miles and used 48 gallons of gas. How many miles did

average salary per player for the Boston Red Sox?

he travel on each gallon of gas?

83. Milligrams of Calcium Suppose one egg contains 25

84. Milligrams of Iron Suppose a glass of juice contains 3

milligrams of calcium, a piece of toast contains 40

milligrams of iron and a piece of toast contains 2

milligrams of calcium, and a glass of milk contains 215

milligrams of iron. If Diane drinks two glasses of juice

milligrams of calcium. How many milligrams of

and has three pieces of toast for breakfast, how much

calcium are contained in a breakfast that consists of

iron is contained in the meal?

three eggs, two glasses of milk, and four pieces of toast?

85. Fitness Walking The guidelines for fitness now indicate

86. Fundraiser As part of a fundraiser for the Earth Day

that a person who walks 10,000 steps daily is

activities on your campus, three volunteers work to

physically fit. According to The Walking Site on the

stuff 3,210 envelopes with information about global

Internet, it takes just over 2,000 steps to walk one

warming. How many envelopes did each volunteer

mile. If that is the case, how many miles do you need

stuff?

to walk in order to take 10,000 steps?

2,000 steps = 1 mile

Exponents, Order of Operations, and Averages Exponents are a shorthand way of writing repeated multiplication. In the expression 23, 2 is called the base and 3 is called the exponent. The expression 23 is read “2 to the third power” or “2 cubed.” The exponent 3 tells us to use the base 2 as a multiplication factor three times. 23  2  2  2

2 is used as a factor three times

We can simplify the expression by multiplication:

1.7 Objectives A Identify the base and exponent of an expression.

B

Simplify expressions with exponents.

C D

Use the rule for order of operations. Find the mean, median, mode, and range of a set of numbers.

23  2  2  2 42 8 The expression 23 is equal to the number 8. We can summarize this discussion

Examples now playing at

with the following definition.

MathTV.com/books

Definition An exponent is a whole number that indicates how many times the base is to be used as a factor. Exponents indicate repeated multiplication.

A Exponents In the expression 52, 5 is the base and 2 is the exponent. The meaning of the expression is 52  5  5

5 is used as a factor two times

 25 The expression 52 is read “5 to the second power” or “5 squared.” Here are some more examples.

EXAMPLE 1

32

The base is 3, and the exponent is 2. The expression is

PRACTICE PROBLEMS For each expression, name the base and the exponent, and write the expression in words. 1. 52

read “3 to the second power” or “3 squared.”

EXAMPLE 2

33

The base is 3, and the exponent is 3. The expression is

2. 23

read “3 to the third power” or “3 cubed.”

EXAMPLE 3

24

The base is 2, and the exponent is 4. The expression is

3. 14

read “2 to the fourth power.” As you can see from these examples, a base raised to the second power is also said to be squared, and a base raised to the third power is also said to be cubed. These are the only two exponents (2 and 3) that have special names. All other exponents are referred to only as “fourth powers,” “fifth powers,” “sixth powers,” and so on.

Answers 1–3. See solutions section.

1.7 Exponents, Order of Operations, and Averages

67

68

Chapter 1 Whole Numbers

B Expressions with Exponents The next examples show how we can simplify expressions involving exponents Simplify each of the following by using repeated multiplication. 4. 52

by using repeated multiplication.

EXAMPLE 4

5. 92

EXAMPLE 5

6. 23

EXAMPLE 6

7. 14

EXAMPLE 7

8. 25

EXAMPLE 8

USING

32  3  3  9

42  4  4  16

33  3  3  3  9  3  27

34  3  3  3  3  9  9  81

24  2  2  2  2  4  4  16

TECHNOLOGY

Calculators Here is how we use a calculator to evaluate exponents, as we did in Example 8: Scientific Calculator: 2 x y 4 Graphing Calculator: 2

^

4

 ENT

or

2 xy 4

ENT

(depending on the calculator)

Finally, we should consider what happens when the numbers 0 and 1 are used as exponents. First of all, any number raised to the first power is itself. That is, if we let the letter a represent any number, then a1  a To take care of the cases when 0 is used as an exponent, we must use the following definition:

Definition Any number other than 0 raised to the 0 power is 1. That is, if a represents any nonzero number, then it is always true that a0  1 Simplify each of the following expressions. 9. 71

10. 41 11. 9

EXAMPLE 9 EXAMPLE 10

51  5

91  9

0

12. 10

EXAMPLE 11

Answers 4. 25 5. 81 6. 8 7. 1 8. 32 9. 7 10. 4 11. 1 12. 1

EXAMPLE 12

40  1

80  1

69

1.7 Exponents, Order of Operations, and Averages

C Order of Operations The symbols we use to specify operations, , ,  , , along with the symbols we use for grouping, ( ) and [ ], serve the same purpose in mathematics as punctuation marks in English. They may be called the punctuation marks of mathematics. Consider the following sentence: Bob said John is tall. It can have two different meanings, depending on how we punctuate it:

1. “Bob,” said John, “is tall.” 2. Bob said, “John is tall.” Without the punctuation marks we don’t know which meaning the sentence has. Now, consider the following mathematical expression: 452 What should we do? Should we add 4 and 5 first, or should we multiply 5 and 2 first? There seem to be two different answers. In mathematics we want to avoid situations in which two different results are possible. Therefore we follow the rule for order of operations.

Definition Order of Operations When evaluating mathematical expressions, we will perform the operations in the following order:

1. If the expression contains grouping symbols, such as parentheses ( ), brackets [ ], or a fraction bar, then we perform the operations inside the grouping symbols, or above and below the fraction bar, first.

2. Then we evaluate, or simplify, any numbers with exponents. 3. Then we do all multiplications and divisions in order, starting at the left and moving right.

4. Finally, we do all additions and subtractions, from left to right.

Note

To help you to remember the order of operations you can use the popular sentence Please Excuse My Dear Aunt Sally, or the acronym PEMDAS Parentheses (or grouping) Exponents Multiplication and Division, from left to right Addition and Subtraction, from left to right

According to our rule, the expression 4  5  2 would have to be evaluated by multiplying 5 and 2 first, and then adding 4. The correct answer—and the only answer—to this problem is 14. 4  5  2  4  10  14

Multiply first Then add

Here are some more examples that illustrate how we apply the rule for order of operations to simplify (or evaluate) expressions.

EXAMPLE 13 SOLUTION

Simplify: 4  8  2  6

We multiply first and then subtract: 4  8  2  6  32  12  20

13. Simplify. a. 5  7  3  6 b. 5  70  3  60

Multiply first Then subtract

Answer 13. a. 17 b. 170

70

14. Simplify: 7  3(6  4)

Chapter 1 Whole Numbers

EXAMPLE 14 SOLUTION

Simplify: 5  2(7  1)

According to the rule for the order of operations, we must do what

is inside the parentheses first: 5  2(7  1)  5  2(6)

Inside parentheses first Then multiply Then add

 5  12  17

15. Simplify. a. 28  7  3 b. 6  32  64  24  2

EXAMPLE 15 SOLUTION

Simplify: 9  23  36  32  8

9  23  36  32  8  9  8  36  9  8

Exponents first

 72  4  8



 76  8  68

USING

Then multiply and divide, left to right Add and subtract, left to right

TECHNOLOGY

Calculators Here is how we use a calculator to work the problem shown in Example 14: Scientific Calculator: 5 Graphing Calculator: 5

 

2 2

 71)  ( 7  1 ) ENT

Example 15 on a calculator looks like this: Scientific Calculator: 9 Graphing Calculator: 9

16. Simplify. a. 5  3[24  5(6  2)] b. 50  30[240  50(6  2)]

EXAMPLE 16 SOLUTION

 

2 xy 3 2

^

3

 

36 36

 

3 xy 2 3

^

2

 

8 8

 ENT

Simplify: 3  2[10  3(5  2)]

The brackets, [ ], are used in the same way as parentheses. In a

case like this we move to the innermost grouping symbols first and begin simplifying: 3  2[10  3(5  2)]  3  2[10  3(3)]  3  2[10  9]  3  2[1] 32 5 Table 1 lists some English expressions and their corresponding mathematical expressions written in symbols.

TABLE 1

In English 5 times the sum of 3 and 8 Twice the difference of 4 and 3 6 added to 7 times the sum of 5 and 6 The sum of 4 times 5 and 8 times 9 3 subtracted from the quotient of 10 and 2

Answers 14. 37 15. a. 1 b. 56 16. a. 17 b. 1,250

Mathematical Equivalent 5(3  8) 2(4  3) 6  7(5  6) 4589 10  2  3

71

1.7 Exponents, Order of Operations, and Averages

DESCRIPTIVE STATISTICS D

Average

Next we turn our attention to averages. If we go online to the MerriamWebster dictionary at www.m-w.com, we find the following definition for the word average when it is used as a noun: av  er  age noun 1a: a single value (as a mean, mode, or

MerriamWebster

median)

that

summarizes

or

represents

the

general

significance of a set of unequal values . . .

®

In everyday language, the word average can refer to the mean, the median, or the mode. The mean is probably the most common average.

Mean Definition To find the mean for a set of numbers, we add all the numbers and then divide the sum by the number of numbers in the set. The mean is sometimes called the arithmetic mean.

EXAMPLE 17

An instructor at a community college earned the

following salaries for the first five years of teaching. Find the mean of these salaries. $35,344

SOLUTION

$38,290

$39,199

$40,346

$42,866

We add the five numbers and then divide by 5, the number of

17. A woman traveled the following distances on a 5-day business trip: 187 miles, 273 miles, 150 miles, 173 miles, and 227 miles. What was the mean distance the woman traveled each day?

numbers in the set. 35,344  38,290  39,199  40,346  42,866 196,045 Mean      39,209 5 5 The instructor’s mean salary for the first five years of work is $39,209 per year.

Median The table below shows the median weekly wages for a number of professions for the first quarter of 2008. WEEKLY WAGES All Americans . . . . . . . . . . . . . . . . . . $719 Butchers . . . . . . . . . . . . . . . . . . . . . . $495 Dietitians. . . . . . . . . . . . . . . . . . . . . . $734 Social workers . . . . . . . . . . . . . . . . . $757 Electricians . . . . . . . . . . . . . . . . . . . . $805 Clergy . . . . . . . . . . . . . . . . . . . . . . . . $797 Special ed teachers . . . . . . . . . . . . . $881 Lawyers. . . . . . . . . . . . . . . . . . . . . . $1591 Source: U.S. Bureau of Labor Statistics (all wages are median figures for 2008)

Answer 17. 202 miles

72

Chapter 1 Whole Numbers If you look at the type at the bottom of the table, you can see that the numbers are the median figures for 2008. The median for a set of numbers is the number such that half of the numbers in the set are above it and half are below it. Here is the exact definition.

Definition To find the median for a set of numbers, we write the numbers in order from smallest to largest. If there is an odd number of numbers, the median is the middle number. If there is an even number of numbers, then the median is the mean of the two numbers in the middle.

18. Find the median for the distances in Practice Problem 17.

Find the median of the numbers given in Example 17.

SOLUTION

The numbers in Example 17, written from smallest to largest, are

shown below. Because there are an odd number of numbers in the set, the median is the middle number. 35,344

38,290

39,199 h

40,346

42,866

median

The instructor’s median salary for the first five years of teaching is $39,199.

A teacher at a community college in California will make 19. A teacher earns the following amounts for the first 4 years he teaches. Find the median. $40,770 $42,635 $44,475 $46,320

the following salaries for the first four years she teaches. $51,890

$53,745

$55,601

$57,412

Find the mean and the median for the four salaries.

SOLUTION

To find the mean, we add the four numbers and then divide by 4: 51,890  53,745  55,601  57,412 218,648     54,662 4 4

To find the median, we write the numbers in order from smallest to largest. Then, because there is an even number of numbers, we average the middle two numbers to obtain the median. 53,745

55,601

57,412

{

51,890

median

g 53,745  55,601   54,673 2 The mean is $54,662, and the median is $54,673.

Mode The mode is best used when we are looking for the most common eye color in a group of people, the most popular breed of dog in the United States, and the movie that was seen the most often. When we have a set of numbers in which one number occurs more often than the rest, that number is the mode.

Definition The mode for a set of numbers is the number that occurs most frequently. If Answers 18. 187 miles 19. $43,555

all the numbers in the set occur the same number of times, there is no mode.

73

1.7 Exponents, Order of Operations, and Averages For example, consider this set of iPods:

{

iPod

iPod

iPod

iPod

iPod

iPod

iPod

iPod

Music

>

Music

>

Music

>

Music

>

Music

>

Music

>

Music

>

Music

>

Photos Extras Settings

> > >

Photos Extras Settings

> > >

Photos Extras Settings

> > >

Photos Extras Settings

> > >

Photos Extras Settings

> > >

Photos Extras Settings

> > >

Photos Extras Settings

> > >

Photos Extras Settings

> > >

MENU

MENU

MENU

MENU

MENU

MENU

MENU

MENU

}

Given the set of iPods the most popular color is red. We call this the mode.

A math class with 18 students had the grades shown

SOLUTION

77

87

100

65

79

87

79

85

87

95

56

87

56

75

79

93

97

92

20. The students in a small math class have the following scores on their final exam. Find the mode. 56 89 74 68 97 74 68 74 88 45

below on their first test. Find the mean, the median, and the mode.

To find the mean, we add all the numbers and divide by 18:

7787100657987798587955687567579939792 18

mean   1,476    82 18

To find the median, we must put the test scores in order from smallest to largest; then, because there are an even number of test scores, we must find the mean of the middle two scores. 56

56

65

75

77

79

79

79

85

87

87

87

87

92

93

95

97

100

85  87 Median    86 2 The mode is the most frequently occurring score. Because 87 occurs 4 times, and no other scores occur that many times, 87 is the mode. The mean is 82, the median is 86, and the mode is 87.

More Vocabulary When we used the word average for the first time in this section, we used it as a noun. It can also be used as an adjective and a verb. Below is the definition of the word average when it is used as a verb.

MerriamWebster

av  er  age verb . . . 2 : to find the arithmetic mean of (a series of unequal quantities) . . .

®

In everyday language, if you are asked for, or given, the average of a set of numbers, the word average can represent the mean, the median, or the mode. When used in this way, the word average is a noun. However, if you are asked to average a set of numbers, then the word average is a verb, and you are being asked to find the mean of the numbers.

Answer 20. 74

74

Chapter 1 Whole Numbers

Range The range of a set of data is the difference between the greatest and least values. While the range of scores on the latest math test may be high, the difference between the highest and lowest gas prices around town will be much smaller.

Average Price per Gallon of Gasoline, July 2008 $4.44 $4.10 $4.07 $4.06 $3.96

Source: http://www.fueleconomy.gov

From the information on average gas prices around the country, we see that the lowest average price was found in Gulf Coast states at $3.96 per gallon with the highest prices being paid on the West Coast at $4.44 per gallon. The range of this set of data is the difference between these two numbers: $4.44  $3.96  $0.48 We say the gas prices in July of 2008 had a range of $0.48.

Definition The range for a set of numbers is the difference between the largest number and the smallest number in the sample.

STUDY SKILLS Read the Book Before Coming to Class As we mentioned in the Preface, it is best to have read the section to be covered in class before getting to class. Even if you don’t understand everything that you have read, you are still better off reading ahead than not. The Getting Ready for Class questions at the end of each section are intended to give you things to look for in the reading that will be important in understanding what is in the section.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. In the expression 53, which number is the base? 2. Give a written description of the process you would use to simplify the expression 3  4(5  6). 3. What is the first step in simplifying the expression 8  6  3  1? 4. What number must we use for x, if the mean of 6, 8, and x is to be 8?

1.7 Problem Set

75

Problem Set 1.7 A For each of the following expressions, name the base and the exponent. [Examples 1–3] 1. 45

2. 54

3. 36

4. 63

7. 91

8. 19

9. 40

10. 04

5. 82

6. 28

B Use the definition of exponents as indicating repeated multiplication to simplify each of the following expressions. [Examples 4–12] 11. 62

12. 72

13. 23

14. 24

15. 14

16. 51

17. 90

18. 270

19. 92

20. 82

21. 101

22. 81

23. 121

24. 160

25. 450

26. 34

C Use the rule for the order of operations to simplify each expression. [Examples 13–16] 27. 16  8  4

28. 16  4  8

29. 20  2  10

30. 40  4  5

31. 20  4  4

32. 30  10  2

33. 3  5  8

34. 7  4  9

35. 3  6  2

36. 5  1  6

37. 6  2  9  8

38. 4  5  9  7

39. 4  5  3  2

40. 5  6  4  3

41. 52  72

42. 42  92

43. 480  12(32)2

44. 360  14(27)2

45. 3  23  5  42

46. 4  32  5  23

47. 8  102  6  43

48. 5  112  3  23

49. 2(3  6  5)

50. 8(1  4  2)

76

Chapter 1 Whole Numbers

51. 19  50  52

52. 9  8  22

53. 9  2(4  3)

54. 15  6(9  7)

55. 4  3  2(5  3)

56. 6  8  3(4  1)

57. 4[2(3)  3(5)]

58. 3[2(5)  3(4)]

59. (7  3)(8  2)

60. (9  5)(9  5)

61. 3(9  2)  4(7  2)

62. 7(4  2)  2(5  3)

63. 18  12  4  3

64. 20  16  2  5

65. 4(102)  20  4

66. 3(42)  10  5

67. 8  24  25  5  32

68. 5  34  16  8  22

69. 5  2[9  2(4  1)]

70. 6  3[8  3(1  1)]

71. 3  4[6  8(2  0)]

72. 2  5[9  3(4  1)]

73. 

15  5(4) 17  12

20  6(2) 11  7

74. 

Translate each English expression into an equivalent mathematical expression written in symbols. Then simplify.

75. 8 times the sum of 4 and 2

76. 3 times the difference of 6 and 1

77. Twice the sum of 10 and 3

78. 5 times the difference of 12 and 6

79. 4 added to 3 times the sum of 3 and 4

80. 25 added to 4 times the difference of 7 and 5

81. 9 subtracted from the quotient of 20 and 2

82. 7 added to the quotient of 6 and 2

83. The sum of 8 times 5 and 5 times 4

84. The difference of 10 times 5 and 6 times 2

D Find the mean and the range for each set of numbers. [Examples 17–20] 85. 1, 2, 3, 4, 5

86. 2, 4, 6, 8, 10

87. 1, 3, 9, 11

88. 5, 7, 9, 12, 12

D Find the median and the range for each set of numbers. [Examples 18–20] 89. 5, 9, 11, 13, 15

90. 42, 48, 50, 64

91. 10, 20, 50, 90, 100

D Find the mode and the range for each set of numbers. [Example 20] 93. 14, 18, 27, 36, 18, 73

94. 11, 27, 18, 11, 72, 11

92. 700, 900, 1100

77

1.7 Problem Set

Applying the Concepts Nutrition Labels Use the three nutrition labels below to work Problems 95–100. CANNED ITALIAN TOMATOES

SPAGHETTI

SHREDDED ROMANO CHEESE

Nutrition Facts

Nutrition Facts

Nutrition Facts

Serving Size 2 oz. (56g/l/8 of pkg) dry Servings Per Container: 8

Serving Size 1/2 cup (121g) Servings Per Container: about 3 1/2

Serving Size 2 tsp (5g) Servings Per Container: 34

Amount Per Serving

Amount Per Serving

Amount Per Serving

Calories 210

Calories from fat 10

Calories 25

% Daily Value* 2%

Total Fat 0g

Total Fat 1g Saturated Fat 0g

0%

Poly unsaturated Fat 0.5g Monounsaturated Fat 0g Cholesterol 0mg

0%

Sodium 0mg

0%

Total Carbohydrate 42g Dietary Fiber 2g

% Daily Value* 0%

Saturated Fat 0g Cholesterol 0mg

0%

Sodium 300mg Potassium 145mg

12% 4%

14%

2% 4%

Vitamin A 20%

• •

Vitamin A 0% Calcium 0%

Sodium 70mg

3%

Total Carbohydrate 0g Fiber 0g

0%

Vitamin A 0%

• •

2%

0%

• •

Vitamin C 0%

Vitamin C 15%

Calcium 4%

Iron 15%

*Percent Daily Values (DV) are based on a 2,000 calorie diet

Vitamin C 0%

Calcium 4%

Iron 10%

*Percent Daily Values are based on a 2,000 calorie diet. Your daily values may be higher or lower depending on your calorie needs.

*Percent Daily Values are based on a 2,000 calorie diet

5%

Protein 2g

Protein 1g

Protein 7g

Saturated Fat 1g Cholesterol 5mg

Sugars 0g

Sugars 4g

7%

Sugars 3g

% Daily Value* 2%

Total Fat 1.5g

0%

Total Carbohydrate 4g Dietary Fiber 1g

Calories from fat 10

Calories 20

Calories from fat 0

Iron 0%

Find the total number of calories in each of the following meals.

95. Spaghetti

1 serving

96. Spaghetti

Tomatoes

1 serving

Tomatoes

2 servings

Tomatoes

1 serving

Tomatoes

1 serving

Cheese

1 serving

Cheese

1 serving

Cheese

1 serving

Cheese

2 servings

1 serving

97. Spaghetti

2 servings

98. Spaghetti

2 servings

Find the number of calories from fat in each of the following meals.

99. Spaghetti

100. Spaghetti

2 servings

2 servings

Tomatoes

1 serving

Tomatoes

1 serving

Cheese

1 serving

Cheese

2 servings

The following table lists the number of calories consumed by eating some popular fast foods. Use the table to work Problems 101 and 102.

101. Compare the total number of calories in the meal

CALORIES IN FOOD Food

in Problem 95 with the number of calories in a Calories

McDonald’s Big Mac.

McDonald’s hamburger

270

Burger King hamburger

260

Jack in the Box hamburger

280

McDonald’s Big Mac

510

Burger King Whopper

630

Problem 98 with the number of calories in a Burger

Jack in the Box Colossus burger

940

King hamburger.

102. Compare the total number of calories in the meal in

78

Chapter 1 Whole Numbers

103. Average If a basketball team has scores of 61, 76, 98, 55, 76, and 102 in their first six games, find a. the mean score

b. the median score

c. the mode of the scores

d. the range of scores

104. Home Sales Below are listed the prices paid for 10 homes that sold during the month of February in a city in Texas. $210,000

$139,000

$122,000

$145,000

$120,000

$540,000

$167,000

$125,000

$125,000

$950,000

a. Find the mean housing price for the month. $1,000,000

$750,000

b. Find the median housing price for the month. $500,000

$250,000

c. Find the mode of the housing prices for the month.

d. Which measure of “average” best describes the average housing price for the month? Explain your answer.

105. Average Enrollment The number of students enrolled in a community college during a 5year period was as follows: Find the mean enrollment and the range of enrollments for this 5-year period.

Year

Enrollment

1999 2000 2001 2002 2003

6,789 6,970 7,242 6,981 6,423

106. Car Prices The following prices were listed for Volkswagen Jettas on the ebay.com car auction site. Use the table to find each of the following:

a. the mean car price CAR PRICES

b. the median car price

c. the mode for the car prices

d. the range of car prices

Year

Price

1998 1999 1999 1999 1999 2000 2000 2001

$10,000 $14,500 $10,500 $11,700 $15,500 $10,500 $18,200 $19,900

20,000

15,000

10,000

5,000

0

98

99

99

99

99

00

00

01

1.7 Problem Set

79

107. Blood Pressure Screening When you have your blood pressure measured, it is written down as two numbers, one over the other. The top number, which is called the systolic pressure, shows the pressure in your arteries when your heart is forcing blood through them. The bottom number, called the diastolic pressure, shows the pressure in your arteries when your heart relaxes. Blood pressure screening is a part of the annual health fair held on your campus. The systolic reading (measured in mmHg) of 10 students were recorded: 140

112

118

120

138

119

130

130

125

128

Use this information to find

a. the mean systolic pressure.

b. the median systolic pressure.

c. the mode for the systolic pressure.

d. the range in the values for systolic pressure.

108. California Counties The table below shows those California counties which had a population of more than 1,000,000 in 2006. Use this information to find the following:

a. the mean population for these counties

b. the median population

c. the mode population

d. the range in the values for the population in these counties

COUNTY POPULATION County

Population

Los Angeles San Diego Orange Riverside San Bernardino Santa Clara Alameda Sacramento Contra Costa

10,294,280 3,120,088 3,098,183 2,070,315 2,039,467 1,820,176 1,530,620 1,415,117 1,044,201

e. Which measure seems to best describe the average population? Explain your choice.

109. Gasoline Prices The Energy Information Administration (EIA) was created by Congress in 1977 and is a statistical agency of the U.S. Department of Energy. According to the EIA, the average retail prices for regular gasoline in California can be seen in the table below. Use this information to find

a. the median price for a gallon of regular gas. AVERAGE PRICE FOR REGULAR GAS IN CALIFORNIA

b. the mode price.

c. the range in the price of regular gas between March 17th and May 5th.

Date 3/17/2008 3/24/2008 3/31/2008 4/07/2008 4/14/2008 4/21/2008 4/28/2008 5/05/2008

Price per Gallon $3.60 $3.60 $3.61 $3.69 $3.77 $3.85 $3.89 $3.90

80

Chapter 1 Whole Numbers

110. Cell Phones The following table shows the total voice minutes and number of calls sent and received for different age groups in 2005 in the US (Telephia Customer Value Metrics, Q3 2005). Use this information to find

a. the mean number of minutes used and the mean number of CELL PHONE USAGE

calls sent and received. Age

b. the range of minutes used and calls sent and received.

c. Based on this information determine the average length of a

18-24 25-36 37-55 56+

Total Voice Minutes Used

Number of Calls Sent/Received

1,304 970 726 441

340 246 197 119

cell phone call.

Extending the Concepts: Number Sequences There is a relationship between the two sequences below. The first sequence is the sequence of odd numbers. The second sequence is called the sequence of squares. 1, 3, 5, 7, . . .

The sequence of odd numbers

1, 4, 9, 16, . . .

The sequence of squares

111. Add the first two numbers in the sequence of odd numbers.

113. Add the first four numbers in the sequence of odd numbers.

112. Add the first three numbers in the sequence of odd numbers.

114. Add the first five numbers in the sequence of odd numbers.

Area and Volume A Area The area of a flat object is a measure of the amount of surface the object has. The area of the rectangle below is 6 square inches, because it takes 6 square inches

1.8 Objectives A Find the area of a polygon. B Find the volume of an object. C Find the surface area of an object.

to cover it.

Examples now playing at

one square inch one square inch one square inch

MathTV.com/books 2 inches

one square inch one square inch one square inch

3 inches A rectangle with an area of 6 square inches

The area of this rectangle can also be found by multiplying the length and the width. Area  (length)  (width)  (3 inches)  (2 inches)  (3  2)  (inches  inches)  6 square inches From this example, and others, we conclude that the area of any rectangle is the product of the length and width. Here are three common geometric figures along with the formula for the area of each one.

w

s s Area = (side)(side) = (side)2 = s2 Square

h

l Area = (length)(width) = lw

b Area = (base)(height) = bh

Rectangle

Parallelogram

1.8 Area and Volume

81

82

Chapter 1 Whole Numbers

PRACTICE PROBLEMS

EXAMPLE 1

1. Find the area.

The parallelogram below has a base of 5 centimeters

and a height of 2 centimeters. Find the area. 2 cm

}

3 cm

2 cm

5 cm

SOLUTION

If we apply our formula we have Area  (base)(height) A  bh 52  10 cm2

Or, we could simply count the number of square centimeters it takes to cover the object. There are 8 complete squares and 4 half-squares, giving a total of 10 squares for an area of 10 square centimeters. Counting the squares in this manner helps us see why the formula for the area of a parallelogram is the product of the base and the height. To justify our formula in general, we simply rearrange the parts to form a rectangle.

Rectangle

Parallelogram h

h b

b Move triangle to right side

2. Find the area of a rectangular

EXAMPLE 2

Find the area of the following stamp.

stamp if it is 35 mm wide and 70 mm long.

Each side is 35 millimeters

SOLUTION

Applying our formula for area we have A  s 2  (35 mm)2  1,225 mm2

Answers 1. 6 cm2

2. 2,450 mm2

83

1.8 Area and Volume

EXAMPLE 3

Find the total area of the house and deck shown below.

3. Find the area of the house without the deck.

27 ft

Deck

10 ft

7 ft

13 ft

Bedroom Dining area Deck

31 ft

Kitchen

Bath

Activity room Laundry

7 ft

Bedroom

SOLUTION

We begin by drawing an additional line, so that the original figure is

now composed of two rectangles. Next, we fill in the missing dimensions on the two rectangles.

50

31 ft

7 13 ft Finally, we calculate the area of the original figure by adding the areas of the individual figures: Area  Area of the small rectangle  Area of the large rectangle 

13  7



50  31



91



1,550

 1,641 square feet

Answer 3. 1,142 sq ft

84

Chapter 1 Whole Numbers

B Volume Next, we move up one dimension and consider what is called volume. Volume is the measure of the space enclosed by a solid. For instance, if each edge of a cube is 3 feet long, as shown in Figure 1, then we can think of the cube as being made up of a number of smaller cubes, each of which is 1 foot long, 1 foot wide, and 1 foot high. Each of these smaller cubes is called a cubic foot. To count the number of them in the larger cube, think of the large cube as having three layers. You can see that the top layer contains 9 cubic feet. Because there are three layers, the total number of cubic feet in the large cube is 9  3  27.

3 ft

3 ft

3 ft

FIGURE 1 A cube in which each edge is 3 feet long On the other hand, if we multiply the length, the width, and the height of the cube, we have the same result: Volume  (3 feet)(3 feet)(3 feet)  (3  3  3)(feet  feet  feet)  27 ft3 or 27 cubic feet

h l

w

Volume = (length)(width)(height) V = lwh FIGURE 2

A Rectangular Solid

4. A home has a dining room that is 12 feet wide and 15 feet long. If the ceiling is 8 feet high, find the volume of the dining room.

For the present we will confine our discussion of volume to volumes of rectangular solids. Rectangular solids are the three-dimensional equivalents of rectangles: Opposite sides are parallel, and any two sides that meet, meet at right angles. A rectangular solid is shown in Figure 2, along with the formula used to calculate its volume.

EXAMPLE 4

Find the volume of a rectangular solid with length 15

inches, width 3 inches, and height 5 inches.

5 in. 15 in.

SOLUTION

To find the volume we apply the formula shown in Figure 2: Vlwh  (15 in.)(3 in.)(5 in.)  225 in3

Answer 4. 1,440 cubic feet

3 in.

85

1.8 Area and Volume

C Surface Area Figure 3 shows a closed box with length l, width w, and height h. The surfaces of the box are labeled as sides, top, bottom, front, and back.

Top

Bac

k

Side

h

Side

Fro nt

tom Bot

l w FIGURE 3 A box with dimensions l, w, and h To find the surface area of the box, we add the areas of each of the six surfaces that are labeled in Figure 3. Surface area  side  side  front  back  top  bottom Slhlhhwhwlwlw  2lh  2hw  2lw

EXAMPLE 5

Find the surface area of the box shown in Figure 4.

5 in.

3 in.

4 in.

5. A family is painting a dining room that is 12 feet wide and 15 feet long. a. If the ceiling is 8 feet high, find the surface area of the walls and the ceiling, but not the floor. b. If a gallon of paint will cover 400 square feet, how many gallons should they buy to paint the walls and the ceiling?

FIGURE 4 A box 4 inches long, 3 inches wide, and 5 inches high

SOLUTION

To find the surface area we find the area of each surface

individually, and then we add them together: Surface area  2(3 in.)(4 in.)  2(3 in.)(5 in.)  2(4 in.)(5 in.)  24 in2  30 in2  40 in2  94 in2 The total surface area is 94 square inches. If we calculate the volume enclosed by the box, it is V  (3 in.)(4 in.)(5 in.)  60 in3. The surface area measures how much material it takes to make the box, whereas the volume measures how much space the box will hold.

Answer 5. a. 612 square feet b. 2 gallons will cover everything, with some paint left over.

86

Chapter 1 Whole Numbers

STUDY SKILLS List Difficult Problems Begin to make lists of problems that give you the most difficulty—those that you are repeatedly making mistakes with.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. If the dimensions of a rectangular solid are given in inches, what units will be associated with the volume? 2. If the dimensions of a rectangular solid are given in inches, what units will be associated with the surface area? 3. How do you find the area of a square? 4. How do you find the area of a parallelogram?

87

1.8 Problem Set

Problem Set 1.8 A Find the area enclosed by each figure. [Examples 1–3] 1.

2.

3.

14 m

5 cm 10 ft 24 m

5 cm 10 ft

4.

5.

6.

6 ft

6 ft

9 in. 10 ft

8 ft

4 in.

7.

8.

3m

9.

10 in.

3m

1 cm

5 in.

6m

4 cm

10 in.

7m

5 in.

4m

2 cm

5 in. 7 cm

9m

5 in.

10.

11.

12.

25 ft

5 ft

5 ft 4 ft

10 m 9m

8 ft 10 ft

4m

30 ft 15 ft

3m 50 ft

15 ft

88

Chapter 1 Whole Numbers

13.

14.

5 cm

10 mm 8 mm

15 cm

8 mm

42 cm

12 mm

22 cm 30 mm

15 cm 42 cm

15. Find the area of a square with side 10 inches.

B

16. Find the area of a square with side 6 centimeters.

C Find the volume and surface area of each figure. [Example 4, 5]

17.

18.

4 cm 10 in. 4 cm

3 in.

12 in.

4 cm

19.

20.

3 cm 4 ft 9 cm 6 ft

5 cm

3 ft

B Find the volume of each figure. [Example 4] 21.

22.

5 ft

8 ft 2 ft 2 ft

7 ft 2 ft 12 ft 3 ft

5 ft 7 ft

10 ft

1.8 Problem Set

89

Applying the Concepts 23. Area A swimming pool is 20 feet wide and 40 feet long.

24. Area A garden is rectangular with a width of 8 feet and

If it is surrounded by square tiles, each of which is 1

a length of 12 feet. If it is surrounded by a walkway 2

foot by 1 foot, how many tiles are there surrounding

feet wide, how many square feet of area does the

the pool?

walkway cover?

25. Comparing Areas The side of a square is 5 feet long. If all

26. Comparing Areas The length of a side in a square is 20

four sides are increased by 2 feet, by how much is the

inches. If all four sides are decreased by 4 inches, by

area increased?

how much is the area decreased?

27. Area of a Euro A 10 euro banknote has a width of 67 millimeters and a length of 127 millimeters. Find the

28. Area of a Dollar A $10 bill has a width of 65 millimeters and a length of 156 millimeters. Find the area.

area.

29. Area of a Stamp The stamp here

30. Area of a Stamp The stamp shown here was issued in 2001 to honor

Kahlo. The image area of the stamp

the Italian scientist Enrico Fermi.

has a width of 20 millimeters and a

The image area of the stamp has

length of 36 millimeter. Find the

a width of 21 millimeters and a

area of the image.

© 2004 Banco de México

shows the Mexican artist Frida

31. Hot Air Balloon The woodcut shows the giant hot air

length of 35 millimeters. Find the area of the image.

32. Reading House Plans Find the area of the floor of the

balloon known as “Le Geant de Nadar” when it was

house shown here if the garage is not included with the

displayed in the Crystal Palace in England in 1868. The

house and if the garage is included with the house.

wicker car of the balloon was two stories, consisting of a 6-compartment cottage with a viewing deck on top. If 6'

6'

26'

the car was 8 feet high with a square base 13 feet on 12'

21'

42'

Garage

27'

each side, find the volume.

21'

6'

12'

Source: Image courtesy of COOLhouseplans.com Science Museum/Science and Society Picture Library

26'

90

Chapter 1 Whole Numbers

Extending the Concepts 33. a. Each side of the red square in the corner is 1 centimeter, and all squares are the same size. On the grid below, draw three more squares. Each side of the first one will be 2 centimeters, each side of the second square will be 3 centimeters, and each side of the third square will be 4 centimeters.

b. Use the squares you have drawn above to complete each of the following tables. PERIMETERS OF SQUARES Length of each Side (in Centimeters)

Perimeter (in Centimeters)

1 2 3 4

AREAS OF SQUARES Length of each Side (in Centimeters)

Area (in Square Centimeters)

1 2 3 4

34. a. The lengths of the sides of the squares in the grid below are all 1 centimeter. The red square has a perimeter of 12 centimeters. On the grid below, draw two different rectangles, each with a perimeter of 12 centimeters.

b. Find the area of each of the three figures in part a.

35. Area of a Square The area of a square is 49 square feet. What is the length of each side?

37. Area of a Rectangle A rectangle has an area of 36 square feet. If the width is 4 feet, what is the length?

36. Area of a Square The area of a square is 144 square feet. How long is each side?

39. Area of a Rectangle A rectangle has an area of 39 square feet. If the length is 13 feet, what is the width?

Chapter 1 Summary EXAMPLES The numbers in brackets indicate the sections in which the topics were discussed.

The margins of the chapter summaries will be used for examples of the topics being reviewed, whenever convenient.

Place Values for Decimal Numbers [1.1] 1. The number 42,103,045 written

The place values for the digits of any base 10 number are as follows: Trillions

Billions

Millions

Thousands

in words is “forty-two million, one hundred three thousand, forty-five.”

Hundreds Ones

Tens

Hundreds

Ones

Tens

Hundreds

Ones

Tens

Hundreds

Ones

Tens

Hundreds

Ones

Tens

Hundreds

The number 5,745 written in expanded form is 5,000  700  40  5

Vocabulary Associated with Addition, Subtraction, Multiplication, and Division [1.2, 1.4, 1.5, 1.6] 2. The sum of 5 and 2 is 5  2.

The word sum indicates addition.

The difference of 5 and 2 is 5  2. The product of 5 and 2 is 5  2. The quotient of 10 and 2 is 10  2.

The word difference indicates subtraction. The word product indicates multiplication. The word quotient indicates division.

Properties of Addition and Multiplication [1.2, 1.5] If a, b, and c represent any three numbers, then the properties of addition and

3. 3  2  2  3 3223 (x  3)  5  x  (3  5) (4  5)  6  4  (5  6) 3(4  7)  3(4)  3(7)

multiplication used most often are: Commutative property of addition: a  b  b  a Commutative property of multiplication: a  b  b  a Associative property of addition: (a  b)  c  a  (b  c) Associative property of multiplication: (a  b)  c  a  (b  c) Distributive property: a(b  c)  a(b)  a(c)

Perimeter of a Polygon [1.2]

4. The perimeter of the rectangle

The perimeter of any polygon is the sum of the lengths of the sides, and it is denoted with the letter P.

below is P  37  37  24  24  122 feet

24 ft

37 ft

Steps for Rounding Whole Numbers [1.3] 5. 5,482 to the nearest ten is

1. Locate the digit just to the right of the place you are to round to.

5,480.

2. If that digit is less than 5, replace it and all digits to its right with zeros.

5,482 to the nearest hundred is 5,500.

3. If that digit is 5 or more, replace it and all digits to its right with zeros, and add 1 to the digit to its left.

Chapter 1

Summary

5,482 to the nearest thousand is 5,000.

91

92

Chapter 1 Whole Numbers

6. Each expression below is undefined. 7 5  0  4/0 0

7. 4  6(8  2)  4  6(6) Inside parentheses first  4  36 Then multiply  40 Then add

Division by 0 (Zero) [1.6] Division by 0 is undefined. We cannot use 0 as a divisor in any division problem.

Order of Operations [1.7] To simplify a mathematical expression:

1. We simplify the expression inside the grouping symbols first. Grouping symbols are parentheses ( ), brackets [ ], or a fraction bar.

2. Then we evaluate any numbers with exponents. 3. We then perform all multiplications and divisions in order, starting at the left and moving right.

4. Finally, we do all the additions and subtractions, from left to right.

8. The mean of 4, 7, 9 and 12 is (4  7  9  12)  4  32  4 8

9. 23  2  2  2  8 5 1 31  3

Average [1.7] The average for a set of numbers can be the mean, the median, or the mode.

Exponents [1.7]

0

In the expression 23, 2 is the base and 3 is the exponent. An exponent is a shorthand notation for repeated multiplication. The exponent 0 is a special exponent. Any nonzero number to the 0 power is 1.

Formulas for Area [1.8] Below are two common geometric figures, along with the formulas for their areas.

s

w

s Area = (side)(side) = (side) 2 = s2 Square

l Area = (length)(width) = lw Rectangle

Formulas for Volume and Surface Area [1.8] The object below is a rectangular solid.

h

l

Volume  V  lwh

w

Surface Area  S  2lh  2hw  2lw

Chapter 1 Review The numbers in brackets indicate the sections in which problems of a similar type can be found.

1. One of the largest Pacific blue marlins was caught near

2. In 2003 the New York Yankees had the highest home

Hawaii in 1982. It weighed 1,376 pounds. Write 1,376 in

attendance in major league baseball. The attendance

words. [1.1]

that year was 3,465,600. Write 3,465,600 in words. [1.1]

For Problems 3 and 4, write each number with digits instead of words. [1.1]

3. Five million, two hundred forty-five thousand, six

4. Twelve million, twelve thousand, twelve

hundred fifty-two

5. In 2003 the Montreal Expos had the lowest attendance

6. According to the American Medical Association, in

in major league baseball. The attendance that year was

2002, there were 215,005 female physicians practicing

1,025,639. Write 1,025,639 in expanded form. [1.1]

medicine in the United States. Write 215,005 in expanded form. [1.1]

Identify each of the statements in Problems 7–14 as an example of one of the following properties. [1.2, 1.5]

a. b. c. d.

e. Commutative property of multiplication f. Associative property of addition g. Associative property of multiplication

Addition property of 0 Multiplication property of 0 Multiplication property of 1 Commutative property of addition

7. 5  7  7  5

8. (4  3)  2  4  (3  2)

9. 6  1  6

10. 8  0  8

11. 5  0  0

12. 4  6  6  4

13. 5  (3  2)  (5  3)  2

14. (6  2)  3  (2  6)  3

Find each of the following sums. (Add.) [1.2]

15.

498  251

16.

784

17. 7,384

 598

251

18.

648

 637

3,592

4,901

Chapter 1

Review

93

94

Chapter 1 Whole Numbers

Find each of the following differences. (Subtract.) [1.4]

19.

20.

789 475

792 178

21.

5,908 2,759

22.

3,527 1,789

Find each of the following products. (Multiply.) [1.5]

23. 8(73)

24. 7(984)

25. 63(59)

26. 49(876)

29. 361 5 ,4 0 8 

30. 2862 1 ,7 3 6 

33. Hundred thousand

34. Million

Find each of the following quotients. (Divide.) [1.6]

27. 692  4

28. 1,020  15

Round the number 3,781,092 to the nearest: [1.3]

31. Ten

32. Hundred

Use the rule for the order of operations to simplify each expression as much as possible. [1.7]

35. 4  3  52

36. 7(9)2  6(4)3

37. 3(2  8  9)

38. 7  2(6  4)

39. 24  6  2

40. 20  3  12  2

41. 4(3  1)3

42. 36  9  32

43. A first-year math student had grades of 80, 67, 78, and

44. If a person has scores of 205, 222, 197, 236, 185, and

91 on the first four tests. What is the student’s mean

215 for six games of bowling, what is the mean score

test grade and median test grade? [1.7]

for the six games and the range of scores for the six games? [1.7]

Write an expression using symbols that is equivalent to each of the following expressions; then simplify. [1.7]

45. 3 times the sum of 4 and 6

46. 9 times the difference of 5 and 3

47. Twice the difference of 17 and 5

48. The product of 5 and the sum of 8 and 2

Applying the Concepts 49. Income and Expenses A person has a monthly income of $1,783 and monthly expenses of $1,295. What is the difference between the monthly income and the expenses? [1.4]

Income

$1,783

Expenses

$1,295

?

50. Number of Sheep A rancher bought 395 sheep and then sold 197 of them. How many were left? [1.4]

Chapter 1

95

Review

Area and Perimeter The rules for soccer state that the playing field must be from 100 to 120 yards long and 55 to 75 yards wide. The 1999 Women’s World Cup was played at the Rose Bowl on a playing field 116 yards long and 72 yards wide. The diagram below shows the smallest possible soccer field, the largest possible soccer field, and the soccer field at the Rose Bowl. [1.2, 1.8]

Soccer Fields 120 yd

116 yd 100 yd 72 yd

75 yd

55 yd

Smallest

Rose Bowl

Largest

51. Find the perimeter of each soccer field.

52. Find the area of each soccer field.

53. Monthly Budget Each month a family budgets $1,150 for

54. Checking Account If a person wrote 23 checks in

rent, $625 for food, and $257 for entertainment. What

January, 37 checks in February, 40 checks in March,

is the sum of these numbers? [1.2]

and 27 checks in April, what is the total number of checks written in the 4-month period? [1.2]

55. Yearly Income A person has a yearly income of $23,256. What is the person’s monthly income? [1.6]

56. Jogging It takes a jogger 126 minutes to run 14 miles. At that rate, how long does it take the jogger to run 1 mile? [1.6]

00:00

02:06

0 miles

57. Take-Home Pay Jeff makes $16 an hour for the first 40

14 miles

58. Take-Home Pay Barbara earns $8 an hour for the first 40

hours he works in a week and $24 an hour for every

hours she works in a week and $12 an hour for every

hour after that. Each week he has $228 deducted from

hour after that. Each week she has $123 deducted from

his check for income taxes and retirement. If he works

her check for income taxes and retirement. What is her

45 hours in one week, how much is his take-home

take-home pay for a week in which she works 50

pay? [1.5]

hours? [1.5]

96

Chapter 1 Whole Numbers

Exercise and Calories The tables below are similar to two of the tables we have worked with in this chapter. Use the information in the tables to work the problems below. [1.2, 1.4, 1.5]

NUMBER OF CALORIES IN FAST FOOD Food

NUMBER OF CALORIES BURNED IN 30 MINUTES

Calories

McDonald’s hamburger Burger King hamburger Jack in the Box hamburger McDonald’s Big Mac Burger King Whopper Jack in the Box Colossus burger Roy Rogers roast beef sandwich McDonald’s Chicken McNuggets (6) Taco Bell chicken burrito McDonald’s french fries (large) Burger King BK Broiler Burger King chicken sandwich

270 260 280 510 630 940 260 300 345 450 540 700

59. How many calories do you consume if you eat one large order of McDonald’s french fries and 2 Big Macs?

130-Pound Person

170-Pound Person

100 105 110 115

130 135 135 145

150 170 250 260

200 235 330 350

Indoor Activities Vacuuming Mopping floors Shopping for food Ironing clothes

Outdoor Activities Chopping wood Ice skating Cross-country skiing Shoveling snow

60. How many calories do you consume if you eat one order of Chicken McNuggets and a McDonald’s hamburger?

61. How many more calories are in one Colossus burger

62. What is the difference in calories between a Whopper and a BK Broiler?

than in two Taco Bell chicken burritos?

63. If you weigh 170 pounds and ice skate for 1 hour, will

64. If you weigh 130 pounds and go cross-country skiing

you burn all the calories consumed by eating one

for 1 hour, will you burn all the calories consumed by

Whopper?

eating one large order of McDonald’s french fries?

65. Suppose you eat a Big Mac and a large order of fries for

66. Suppose you weigh 170 pounds and you eat two Taco

lunch. If you weigh 130 pounds, what combination of

Bell chicken burritos for lunch. What combination of

30-minute activities could you do to burn all the

30-minute activities could you do to burn all the

calories you consumed at lunch?

calories in the burritos?

67. Find the volume and surface area of the rectangular

68. Find the volume and surface area of the rectangular solid given. [1.8]

solid given. [1.8]

5 cm

4 cm

4 cm 8 cm

2 cm 6 cm

Chapter 1 Test 1. Write the number 20,347 in words.

2. Write the number two million, forty-five thousand, six with digits instead of words.

3. Write the number 123,407 in expanded form.

Identify each of the statements in Problems 4–7 as an example of one of the following properties.

a. b. c. d.

e. Commutative property of multiplication f. Associative property of addition g. Associative property of multiplication

Addition property of 0 Multiplication property of 0 Multiplication property of 1 Commutative property of addition

4. (5  6)  3  5  (6  3)

5. 7  1  7

6. 9  0  9

7. 5  6  6  5

Find each of the following sums. (Add.)

8.

135

9.

 741

5,401 329  10,653

Find each of the following differences. (Subtract.)

10.

937  413

11.

7,052  3,967

Find each of the following products. (Multiply.)

12. 9(186)

13. 62(359)

Find each of the following quotients. (Divide.)

14. 1,105  13

15. 5831 2 ,2 4 3 

16. Round the number 516,249 to the nearest ten thousand.

Chapter 1

Test

97

98

Chapter 1 Whole Numbers

Use the rule for the order of operations to simplify each expression as much as possible.

17. 8(5)2  7(3)3

18. 8  2(5  3)

19. 7  2(53  3)

20. 3(x  2)

21. Home Sales Below are listed the prices paid for 10 homes that sold during the month of February in the city of White Bear Lake. Find the mean, median, and mode from these prices. $210,000

$139,000

$122,000

$145,000

$120,000

$540,000

$167,000

$125,000

$125,000

$950,000

Translate into symbols, then simplify.

22. Twice the sum of 11 and 7

23. The quotient of 20 and 5 increased by 9

24. Hours of Commuting In 2001 the Texas Transportation Institute conducted a study of the number of hours a year commuters spent in gridlock in the country’s 68 largest urban areas. The top five areas from that study are listed in the bar chart below. Use the information in the bar chart to complete the table.

Time Spent in Gridlock Average Hours in Gridlock Per Year

90 80

Urban Area

60

Los Angeles Washington Seattle-Everett

52 35

40 30

32

34

Atlanta

50

Seattle-Everett

Hours

70

52

34

29

Boston

20 10 Boston

Washington

Los Angeles

0

25. Geometry Find the perimeter and the area of the rectangle below.

26. Geometry Find the volume and surface area of the rectangular solid given.

5 cm

3 ft

4 ft

2 cm 7 cm

Chapter 1 Projects WHOLE NUMBERS

GROUP PROJECT Egyptian Numbers Number of People Time Needed Equipment Background

3 10 minutes Pencil and paper The Egyptians had a fully developed number system as early as 3500 B.C. They recorded very large numbers in the macehead of Narmer, which boasts of the spoils taken during wars, and the Book of the Dead, a collection of religious texts. The Egyptians used a base-ten system. A special pictograph was used to represent each power of ten. Here are some pictographs used.

Example

1

10

100

1,000

10,000

100,000

1,000,000

1

2

3

4

5

6

7

staff

horseshoe

rope

lotus flower

bent finger

tadpole or frog

astonished person

Usually the direction of writing was from right

Express each of the given numbers in Egyptian

to left, with the larger units first. Symbols were

hieroglyphics.

placed in rows to save lateral space. Writing the number 132,146 in Egyptian hieroglyphics looks

4. 4,310,175

like this: 132,146 

Procedure

3. 1,842

111 222 3 44 555 111 2

6

Write each of the following Egyptian numbers in our system. 1.

2.

1111 222 333 4444 77 1111 222 33 444 222 222 4444 55555 66 7

Students and Instructors: The end of each chapter in this book will have two projects. The group projects are intended to be done in class. The research projects are to be completed outside of class. They can be done in groups or individually.

Chapter 1

Projects

99

RESEARCH PROJECT Leopold Kronecker Leopold Kronecker (1823–1891) was a German mathematician and logician who thought that arithmetic should be based on whole numbers. He is known for the quote, “God made the natural numbers; all else is the work of man.” He was openly critical of the efforts of his contemporaries. Kronecker’s primary work was in the field of algebraic number theory. Research the life of Leopold Kronecker, or discuss the work of a mathematician who was criticized by Kronecker.

100

Chapter 1 Whole Numbers

Courtesy of Wolfram Research/ National Science Foundation

A Glimpse of Algebra At the end of most chapters of this book you will find a section like this one. These sections show how some of the material in the chapter looks when it is extended to algebra. If you are planning to take an algebra course after you have finished this one, these sections will give you a head start. If you are not planning to take algebra, these sections will give you an idea of what algebra is like. Who knows? You may decide to take an algebra class after you work through a few of these sections. In this chapter we did some work with exponents. We can use the definition of exponents, along with the commutative property of multiplication, to rewrite some expressions that contain variables and exponents. We can expand the expression (5x)2 using the definition of exponents as (5x)2  (5x)(5x) Because the expression on the right is all multiplication, we can rewrite it as (5x)(5x)  5  x  5  x And because multiplication is a commutative operation, we can rearrange this last expression so that the numbers are grouped together, and the variables are grouped together: 5  x  5  x  (5  5)(x  x) Now, because 5  5  25

and

x  x  x2

we can rewrite the expression as (5  5)(x  x)  25x 2 Here is what the problem looks like when the steps are shown together: (5x)2  (5x)(5x)  (5  5)(x  x)  25x 2

Definition of exponents Commutative property Multiplication and definition of exponents

We have shown only the important steps in this summary. We rewrite the expression by (1) applying the definition of exponents to expand it, (2) rearranging the numbers and variables by using the commutative property, and then (3) simplifying by multiplication. Here are some more examples.

EXAMPLE 1

PRACTICE PROBLEMS Expand (7x) using the definition of exponents, and then 2

of exponents, and then simplify the result.

simplify the result.

SOLUTION

1. Expand (3x)2 using the definition

We begin by writing the expression as (7x)(7x), then rearranging

the numbers and variables, and then simplifying: (7x)2  (7x)(7x)

Definition of exponents

 (7  7)(x  x) Commutative property  49x 2

Multiplication and definition of exponents

Answer 1. 9x 2

A Glimpse of Algebra

101

102

2. Expand and simplify: (2a)3

Chapter 1 Whole Numbers

EXAMPLE 2 SOLUTION

Expand and simplify: (5a)3

We begin by writing the expression as (5a)(5a)(5a): (5a)3  (5a)(5a)(5a)

Definition of exponents  (5  5  5)(a  a  a) Commutative property  125a3 5  5  5  125; a  a  a  a 3

3. Expand and simplify: (7xy)2

EXAMPLE 3 SOLUTION

Expand and simplify: (8xy)2

Proceeding as we have above, we have: (8xy)2  (8xy)(8xy)

Definition of exponents

 (8  8)(x  x)(y  y) Commutative property  64x 2y 2 4. Simplify: (3x)2(7xy)2

EXAMPLE 4 SOLUTION

8  8  64; x  x  x 2; y  y  y 2

Simplify: (7x)2(8xy)2

We begin by applying the definition of exponents: (7x)2(8xy)2  (7x)(7x)(8xy)(8xy)  (7  7  8  8)(x  x  x  x)(y  y)

Commutative property

 3,136x 4y 2 5. Simplify: (5x)3(2x)2

EXAMPLE 5 SOLUTION

Simplify: (2x)3(4x)2

Proceeding as we have above, we have: (2x)3(4x)2  (2x)(2x)(2x)(4x)(4x)  (2  2  2  4  4)(x  x  x  x  x)  128x 5

Answers 2. 8a 3 3. 49x 2y 2 4. 441x 4y 2 5. 500x 5

A Glimpse of Algebra Problems

103

A Glimpse of Algebra Problems Use the definition of exponents to expand each of the following expressions. Apply the commutative property, and simplify the result in each case.

1. (6x)2

2. (9x)2

3. (4x)2

4. (10x)2

5. (3a)3

6. (6a)3

7. (2ab)3

8. (5ab)3

9. (9xy)2

10. (5xy)2

11. (5xyz)2

12. (7xyz)2

13. (4x)2(9xy)2

14. (10x)2(5xy)2

15. (2x)2(3x)2(4x)2

16. (5x)2(2x)2(10x)2

104

Chapter 1 Whole Numbers

17. (2x)3(5x)2

18. (3x)3(4x)2

19. (2a)3(3a)2(10a)2

20. (3a)3(2a)2(10a)2

21. (3xy)3(4xy)2

22. (2xy)4(3xy)2

23. (5xyz)2(2xyz)4

24. (6xyz)2(3xyz)3

25. (xy)3(xz)2( yz)4

26. (xy)4(xz)2( yz)3

27. (2a 3b 2)2(3a 2b 3)4

28. (4a 4b 3)2(5a 2b 4)2

29. (5x 2y 3)(2x 3y 3)3

30. (8x 2y 2)2(3x 3y 4)2

Fractions and Mixed Numbers

2 Chapter Outline 2.1 The Meaning and Properties of Fractions 2.2 Prime Numbers, Factors, and Reducing to Lowest Terms 2.3 Multiplication with Fractions, and the Area of a Triangle 2.4 Division with Fractions 2.5 Addition and Subtraction with Fractions 2.6 Mixed-Number Notation

Introduction

2.7 Multiplication and Division with Mixed Numbers

Crater Lake, located in the Cascade Mountain range in Southern Oregon, is 594

2.8 Addition and Subtraction with Mixed Numbers

meters deep, making it the deepest lake in the United States. Here is a chart showing the depth of Crater Lake and the location of some lakes that are deeper than Crater Lake.

2.9 Combinations of Operations and Complex Fractions

668 m

O’Higgins-San Martin

594 m

Issyk Kul

Crater Lake

Deepest Lakes in the World

1,470 m

Baikal

Tanganyika

836 m

1,637 m

As you can see from the chart, although Crater lake is the deepest lake in the United States, it is far from being the deepest lake in the world. We can use fractions to compare the depths of these lakes. For example, Crater Lake is approximately

2  5

as deep as Lake Tanganyika. In this chapter, we begin our work with

fractions.

105

Chapter Pretest The pretest below contains problems that are representative of the problems you will find in the chapter. 16 20

1. Reduce to lowest terms: 

2. Factor 112 into a product of prime factors.

Perform the indicated operations. Reduce all answers to lowest terms. 3 8

4. 10  

3 4

7.   

32 45

5 16

6.   9

40 63

5

5.   

7 20

8.   

6

3.   16

5 8

3 5

1 6

21 8

9. Write 4  as an improper fraction.

10. Write  as a mixed number.

Perform the indicated operations. Reduce all answers to lowest terms. 3 8

1 6

4 5

11. 1   2 

1 5

12. 12  3 

1 10

1 6

13. 4   1 

1 3

14. 6   3 

Simplify each of the following as much as possible.

15.

1

 4 

2

1 18. 1   4



16.

1 2 1    3 3



1

 3 

2

3  27   2

 

2

4

10 9

1 2   4 20.  1 2   4

3  5 19.  9  10



9 10

17. 12    

Getting Ready for Chapter 2 The problems below review material covered previously that you need to know in order to be successful in Chapter 2. If you have any difficulty with the problems here, you need to go back and review before going on to Chapter 2.

1. Place either  or between the two numbers so that the resulting statement is true. a. 9 5 b. 10 0 c. 0 1 d. 2001 201 Simplify.

2. 2  5

3. 5  3

4. 13  12  9

5. 5  4  3

6. 64  8  2

7. 17  (3  5  2)

8. (3  5)(2  1)

9. 3  2(3  4)2

10. 32  42  75  52

The following division problems all have remainders. Divide.

11. 11  4

12. 208  24

15. Use the distributive property to rewrite 2  7  3  7.

106

Chapter 2 Fractions and Mixed Numbers

13. 8,648  43

14. 14,713  29

16. Rewrite using exponents: 2  2  3  3  3.

The Meaning and Properties of Fractions

Objectives A Identify the numerator and

Introduction . . . The information in the table below was taken from the website for Cal Poly. The pie chart was created from the table. Both the table and pie chart use fractions to specify how the students at Cal Poly are distributed among the different schools within the university.

Cal Poly Enrollment for Fall

CAL POLY ENROLLMENT FOR FALL School

2.1 denominator of a fraction.

B

Identify proper and improper fractions.

C D E

Write equivalent fractions. Simplify fractions with division. Compare the size of fractions.

Fraction Of Students

Agriculture

11  50

Architecture and Environmental Design

1  10

Business

3  20

Engineering

1  4

Examples now playing at

MathTV.com/books Liberal Arts

4 – 25

Note

3 Science and Mathematics –

When we use a letter to represent a number, or a group of numbers, that letter is called a variable. In the definition below, we are restricting the numbers that the variable b can represent to numbers other than 0. As you will see later in the chapter, we do this to avoid writing an expression that would imply division by the number 0.

25

Liberal Arts

4  25

Science and Mathematics

3  25

Agriculture

11 – 50

Architecture and Environmental Design

1 – 10

3 20

Business – 1 Engineering – 4

From the table, we see that

1  4

(one-fourth) of the students are enrolled in the

School of Engineering. This means that one out of every four students at Cal Poly is studying engineering. The fraction

1  4

tells us we have 1 part of 4 equal parts.

Figure 1 at the right shows a rectangle that has been divided into equal parts in four different ways. The shaded area for each rectangle is

1  2

the total area.

Now that we have an intuitive idea of the meaning of fractions, here are the more formal definitions and vocabulary associated with fractions.

A The Numerator and Denominator

a.

1 2

is shaded

b.

2 4

are shaded

c.

3 6

are shaded

d.

4 8

are shaded

Definition a A fraction is any number that can be put in the form  (also sometimes b written a/b), where a and b are numbers and b is not 0.

Some examples of fractions are: 1  2

3  4

7  8

9  5

One-half

Three-fourths

Seven-eighths

Nine-fifths

STUDY SKILLS Intend to Succeed I always have a few students who simply go through the motions of studying without intending to master the material. It is more important to them to look like they are studying than to actually study. You need to study with the intention of being successful in the course no matter what it takes.

2.1 The Meaning and Properties of Fractions

1

FIGURE 1 Four Ways to Visualize 2

107

108

Chapter 2 Fractions and Mixed Numbers

Definition a For the fraction , a and b are called the terms of the fraction. More b specifically, a is called the numerator, and b is called the denominator. a m numerator fraction  b m denominator

PRACTICE PROBLEMS 1. Name the terms of the fraction 5 . 6

Which is the numerator and which is the denominator?

2. Name the numerator and the denominator of the fraction

x . 3

3. Why is the number 9 considered to be a fraction?

EXAMPLE 1

3 The terms of the fraction  are 3 and 4. The 3 is called 4 the numerator, and the 4 is called the denominator.

EXAMPLE 2

a The numerator of the fraction  is a. The denominator is 5 5. Both a and 5 are called terms.

EXAMPLE 3

The number 7 may also be put in fraction form, because it 7 can be written as . In this case, 7 is the numerator and 1 is the denominator. 1

B Proper and Improper Fractions Definition 4. Which of the following are 1  6

fraction is called an improper fraction.

8  5

2  3

A proper fraction is a fraction in which the numerator is less than the denominator. If the numerator is greater than or equal to the denominator, the

proper fractions?

5. Which of the following are

EXAMPLE 4

improper fractions? 5  9

6  5

4  3

7

Note

There are many ways to give meaning to 2 fractions like 3 other than by using the number line. One popular way is to think of cutting a pie into three equal pieces, as shown below. If you take two of 2 the pieces, you have taken 3 of the pie.

and

9  10

are all proper fractions, be-

cause in each case the numerator is less than the denominator.

EXAMPLE 5

9 10  ,   , 5 10

The numbers

and 6 are all improper fractions, be-

cause in each case the numerator is greater than or equal to the denominator. 6

(Remember that 6 can be written as 1, in which case 6 is the numerator and 1 is the denominator.)

Fractions on the Number Line 2

We can give meaning to the fraction 3 by using a number line. If we take that part of the number line from 0 to 1 and divide it into three equal parts, we say that we have divided it into thirds (see Figure 2). Each of the three segments is

1 3 1 3

3 1  ,  , 4 8

The fractions

third) of the whole segment from 0 to 1. 1 3

Answers 1. Terms: 5 and 6; numerator: 5; denominator: 6 2. Numerator: x; denominator: 3 9 3. Because it can be written  1 1 2 6 4 4. ,  5. , , 7 6 3 5 3

1 3

1 3

0

1 3

1 FIGURE 2

1  3

(one

109

2.1 The Meaning and Properties of Fractions Two of these smaller segments together are ment. And three of them would be

3  3

2  3

(two thirds) of the whole seg-

(three thirds), or the whole segment, as

indicated in Figure 3. 3 3 2 3 1 3

0

1 3

1

2 3

FIGURE 3 Let’s do the same thing again with six and twelve equal divisions of the segment from 0 to 1 (see Figure 4). The same point that we labeled with with

4 . 12

1  3

in Figure 3 is now labeled with

2  6

and

It must be true then that 1 4 2      12 6 3

Although these three fractions look different, each names the same point on the number line, as shown in Figure 4. All three fractions have the same value, because they all represent the same number.

0

1 3

0 0

1 6 1 12

2 12

2 3

2 6 3 12

4 12

3 6 5 12

6 12

3 3

4 6 7 12

8 12

5 6 9 12

10 12

11 12

1 3

=1

1 3

6 6

=1

12 12

=1

FIGURE 4

C Equivalent Fractions Definition Fractions that represent the same number are said to be equivalent. Equivalent fractions may look different, but they must have the same value.

It is apparent that every fraction has many different representations, each of which is equivalent to the original fraction. The next two properties give us a way of changing the terms of a fraction without changing its value.

1 3

1 6

1 3 2 3

2 6

=

=

1 1 6 6 1 1 6 6 4 6

4 12

= 1 12 1 12

1 6

=

1 1 1 12 12 1 12 12

1 1 12 1 1 12 12 12

8 12

1 12 1 12

110

Chapter 2 Fractions and Mixed Numbers

Property 1 for Fractions If a, b, and c are numbers and b and c are not 0, then it is always true that a ac    b bc In words: If the numerator and the denominator of a fraction are multiplied by the same nonzero number, the resulting fraction is equivalent to the original fraction.

2 3 tion with denominator 12.

6. Write  as an equivalent frac-

EXAMPLE 6 SOLUTION

Write

3  4

as an equivalent fraction with denominator 20.

The denominator of the original fraction is 4. The fraction we are

trying to find must have a denominator of 20. We know that if we multiply 4 by 5, we get 20. Property 1 indicates that we are free to multiply the denominator by 5 so long as we do the same to the numerator. 3 35 15        4 45 20 15

3

The fraction 2 is equivalent to the fraction 4. 0 2 3 tion with denominator 12x.

7. Write  as an equivalent frac-

EXAMPLE 7 SOLUTION

Write

3  4

as an equivalent fraction with denominator 12x.

If we multiply 4 by 3x, we will have 12x: 9x 3  3x 3      4 12x 4  3x

Property 2 for Fractions If a, b, and c are integers and b and c are not 0, then it is always true that a ac    b bc In words: If the numerator and the denominator of a fraction are divided by the same nonzero number, the resulting fraction is equivalent to the original fraction.

15 20 fraction with denominator 4.

8. Write  as an equivalent

EXAMPLE 8 SOLUTION

10

Write 1 as an equivalent fraction with denominator 6. 2

If we divide the original denominator 12 by 2, we obtain 6. Property

2 indicates that if we divide both the numerator and the denominator by 2, the resulting fraction will be equal to the original fraction: 10 10  2 5        12 12  2 6

Answers 8 12

6. 

8x 12x

7. 

3 4

8. 

111

2.1 The Meaning and Properties of Fractions

D The Number 1 and Fractions There are two situations involving fractions and the number 1 that occur frequently in mathematics. The first is when the denominator of a fraction is 1. In this case, if we let a represent any number, then a   a 1

for any number a

The second situation occurs when the numerator and the denominator of a fraction are the same nonzero number: a   1 a

for any nonzero number a

EXAMPLE 9 24 1

48 24

24 24

a.  SOLUTION

9. Simplify.

Simplify each expression. 72 24

c. 

b. 

d. 

In each case we divide the numerator by the denominator: 24 1

48 24

24 24

a.   24

c.   2

b.   1

18 a.  1

18 b.  18

36 c.  18

72 d.  18

72 24

d.   3

E Comparing Fractions We can compare fractions to see which is larger or smaller when they have the same denominator.

EXAMPLE 10

Write each fraction as an equivalent fraction with denom-

inator 24. Then write them in order from smallest to largest. 5  8

SOLUTION

5  6

3  4

2  3

10. Write each fraction as an equivalent fraction with denominator 12. Then write in order from smallest to largest. 1 1 1 5 , , ,  3 6 4 12

We begin by writing each fraction as an equivalent fraction with

denominator 24. 5 15     8 24

5 20     6 24

3 18     4 24

2 16     3 24

Now that they all have the same denominator, the smallest fraction is the one with the smallest numerator and the largest fraction is the one with the largest numerator. Writing them in order from smallest to largest we have: 15  24



16  24



18  24



20  24

3  4



5  6

or 5  8



2  3



STUDY SKILLS Be Focused, Not Distracted I have students who begin their assignments by asking themselves, “Why am I taking this class?” or, “When am I ever going to use this stuff?” If you are asking yourself similar questions, you may be distracting yourself from doing the things that will produce the results you want in this course. Don’t dwell on questions and evaluations of the class that can be used as excuses for not doing well. If you want to succeed in this course, focus your energy and efforts toward success.

Answers 9. a. 18 b. 1 c. 2 d. 4 10. 122 , 132 , 142 , 152

Chapter 2 Fractions and Mixed Numbers

DESCRIPTIVE STATISTICS Scatter Diagrams and Line Graphs The table and bar chart give the daily gain in the price of a certain stock for one week, when stock prices were given in terms of fractions instead of decimals.

Daily Gain Change in Stock Price Day

1 Gain

Tuesday

9  16

Wednesday

3  32

Thursday

7  32

Friday

1  16

3/4

3 – 4

3  4

Monday

9/16 1 – 2 1 – 4

7/32 3/32

1/16

0 M

T

W

Th

F

FIGURE 5 Bar Chart

Figure 6 below shows another way to visualize the information in the table. It is called a scatter diagram. In the scatter diagram, dots are used instead of the bars shown in Figure 5 to represent the gain in stock price for each day of the week. If we connect the dots in Figure 6 with straight lines, we produce the diagram in Figure 7, which is known as a line graph.

1

1

3 – 4

3 – 4

Gain ($)

Gain ($)

112

1 – 2 1 – 4

1 – 2 1 – 4

0

0 M

T

W

Th

F

FIGURE 6 Scatter Diagram

M

T

W

Th

F

FIGURE 7 Line Graph

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. An answer of yes or no should always be accompanied by a sentence explaining why the answer is yes or no. 1. Explain what a fraction is.

7

2. Which term in the fraction 8 is the numerator? 3

3. Is the fraction 9 a proper fraction?

1

4

4. What word do we use to describe fractions such as 5 and 2 , which look 0 different, but have the same value?

113

2.1 Problem Set

Problem Set 2.1 A Name the numerator of each fraction. [Examples 1–3] 1 3

2. 

x 8

6. 

1. 

5. 

1 4

3. 

2 3

4. 

2 4

y 10

7. 

a b

8. 

11. 6

12. 2

x y

A Name the denominator of each fraction. [Examples 1–3] 2 5

10. 

3 5

a 12

14. 

9. 

b 14

13. 

A Complete the following tables. 15.

Numerator

Denominator

a

b

3

5

Fraction a  b

16.

Numerator

Denominator

a

b

2

9

1  7

1

x  y

y x1

x

Fraction a  b

4  3

3 1

1  x

x

x  x1

B 17. For the set of numbers {4, 5, 3, 2, 1 ,  , list all the 0 10 } 3

6

12

1

9

20

proper fractions.

18. For the set of numbers {8, 9, 3, 6, 5, 8}, list all the im1

7

6

18

3

9

proper fractions.

Indicate whether each of the following is True or False.

19. Every whole number greater than 1 can also be ex-

20. Some improper fractions are also proper fractions.

pressed as an improper fraction.

C 21. Adding the same number to the numerator and the denominator of a fraction will not change its value.

3

9

22. The fractions 4 and 1 are equivalent. 6

114

Chapter 2 Fractions and Mixed Numbers

C Divide the numerator and the denominator of each of the following fractions by 2. [Examples 6–8] 6 8

10 12

23. 

86 94

24. 

106 142

25. 

26. 

C Divide the numerator and the denominator of each of the following fractions by 3. [Examples 6–8] 12 9

33 27

27. 

39 51

28. 

57 69

29. 

30. 

C Write each of the following fractions as an equivalent fraction with denominator 6. [Examples 6–8] 2 3

1 2

31. 

55 66

32. 

65 78

33. 

34. 

C Write each of the following fractions as an equivalent fraction with denominator 12. [Examples 6–8] 2 3

5 6

35. 

56 84

36. 

143 156

37. 

38. 

C Write each fraction as an equivalent fraction with denominator 12x. [Example 7] 1 6

3 4

39. 

40. 

C Write each number as an equivalent fraction with denominator 24a. [Example 7] 41. 2

42. 1

43. 5

45. One-fourth of the first circle below is shaded. Use the

44. 8

46. The objects below are hexagons, six-sided figures. One-

other three circles to show three other ways to shade

third of the first hexagon is shaded. Shade the other

one-fourth of the circle.

three hexagons to show three other ways to represent one-third.

D Simplify by dividing the numerator by the denominator. 3 1

47. 

3 3

48. 

6 3

49. 

12 3

50. 

37 1

51. 

37 37

52. 

2.1 Problem Set

115

53. For each square below, what fraction of the area is given by the shaded region? b.

a.

c.

d.

54. For each square below, what fraction of the area is given by the shaded region? b.

a.

c.

d.

The number line below extends from 0 to 2, with the segment from 0 to 1 and the segment from 1 to 2 each divided into 8 equal parts. Locate each of the following numbers on this number line. 1 4

56. 

15 16

61. 

55. 

60. 

1 8

57. 

3 2

62. 

0

E

5 8

59. 

31 16

64. 

1 16

58. 

5 4

63. 

1

3 4

15 8

2

[Example 10]

65. Write each fraction as an equivalent fraction with denominator 100. Then write them in order from smallest to largest. 3  10

1  20

4  25

2  5

66. Write each fraction as an equivalent fraction with denominator 30. Then write them in order from smallest to largest. 1  15

5  6

7  10

1  2

116

Chapter 2 Fractions and Mixed Numbers

Applying the Concepts 67. Rainfall The chart shows the average rainfall for

68. Rainfall The chart shows the average rainfall for

Death Valley in the given months. Write the rainfall for

Death Valley in the given months. Write the rainfall for

January as an equivalent fraction with denominator 12.

April as an equivalent fraction with denominator 75.

Death Valley Rainfall

Death Valley Rainfall 1 2

1 4

1 4

1 4

0

Jan

Mar

1 4 1 10

1 10

May

Jul

inches

measured in inches

1 2

1 4

1 3

1 4

3 25

0

Sep

Feb

Nov

Apr

1 20

1 10

Jun

Aug

1 4

1 4

Oct

Dec

69. Sending E-mail The pie chart below shows the fraction of workers who responded to a survey about sending nonwork-related e-mail from the office. Use the pie chart to fill in the table.

Workers sending personal e-mail from the office Never

4 –– 25

47 ––– 100 8 5-10 times day –– 25 1 >10 times a day –– 20

1-5 times a day

How Often Workers Send Non-Work-Related E-Mail From the Office

Fraction of Respondents Saying Yes

never 1 to 5 times a day 5 to 10 times a day more than 10 times a day

70. Surfing the Internet The pie chart below shows the fraction of workers who responded to a survey about viewing nonwork-related sites during working hours. Use the pie chart to fill in the table. How Often Workers View Non-Work-Related Sites From the Office

Workers surfing the net from the office Constantly Never

9 ––– 100

37 ––– 100 8 –– 25 11 week –– 50

A few times a day A few times a

never a few times a week a few times a day constantly

Fraction of Respondents Saying Yes

2.1 Problem Set 71. Number of Children If there are 3 girls in a family with 5 children, then we say that

3  5

117

72. Medical School If 3 out of every 7 people who apply to

of the children are girls. If

medical school actually get accepted, what fraction of

there are 4 girls in a family with 5 children, what frac-

the people who apply get accepted?

tion of the children are girls?

73. Downloaded Songs The new iPod™ Shuffle will hold up

74. Cell Phones In a survey of 1,000 cell phone subscribers

to 500 songs. You load 311 of your favorite tunes onto

it was determined that 160 subscribers owned more

your iPod. Represent the number of songs on your iPod

than one cell phone and used different carriers for each

as a fraction of the total number of songs it can hold.

phone. Represent the number of cell phone subscribers with more than one carrier as a fraction.

75. College Basketball Recently the men’s basketball team at

76. Score on a Test Your math teacher grades on a point sys-

the University of Maryland won 19 of the 33 games

tem. You take a test worth 75 points and score a 67 on

they played. What fraction represents the number of

the test. Represent your score as a fraction.

games won?

77. Circles A circle measures 360 degrees, which is commonly written as 360°. The shaded region of each of the circles below is given in degrees. Write a fraction that represents the area of the shaded region for each of these circles.

a.

b.

c.

90°

d.

45°

180°

270°

78. Carbon Dating All living things contain a small amount of carbon-14, which is radioactive and decays. The half-life of carbon-14 is 5,600 years. During the lifetime of an organism, the carbon-14 is replenished, but after its death the carbon-14 begins to disappear. By measuring the amount left, the age of the organism can be determined with surprising accuracy. The line graph below shows the fraction of carbon-14 remaining after the death of an organism. Use the line graph to complete the table. 1

Years Since Death of Organism

Fraction of Carbon-14 Remaining

0

1 1  2

11,200

Fraction of carbon-14 remaining

Concentration of Carbon-14

3/4

1/2

1/4

16,800 0

1  16

5,600

11,200

16,800

Years since death

22,400

118

Chapter 2 Fractions and Mixed Numbers

Estimating 79. Which of the following fractions is closest to the number 0? 1 a.  2

1 b.  3

1 c.  4

1 d.  5

81. Which of the following fractions is closest to the number 0? 1 a.  8

3 b.  8

5 c.  8

7 d.  8

80. Which of the following fractions is closest to the number 1? 1 a.  2

1 3

b. 

1 4

c. 

1 5

d. 

82. Which of the following fractions is closest to the number 1? 1 a.  8

3 8

b. 

5 8

c. 

Getting Ready for the Next Section Multiply.

83. 2  2  3  3  3

84. 22  33

85. 22  3  5

86. 2  32  5

87. 12  3

88. 15  3

89. 20  4

90. 24  4

91. 42  6

92. 72  8

93. 102  2

94. 105  7

97. 5  24  3  42

98. 7  82  2  52

Divide.

Maintaining Your Skills The problems below review material covered previously. Simplify.

95. 3  4  5

99. 4  3  2(5  3)

96. 20  8  2

100. 6  8  3(4  1)

101. 18  12  4  3

7 8

d. 

102. 20  16  2  5

Prime Numbers, Factors, and Reducing to Lowest Terms

Objectives A Identify numbers as prime or

Introduction . . . Suppose you and a friend decide to split a medium-sized pizza for lunch. When the pizza is delivered you find that it has been cut into eight equal pieces. If you eat four pieces, you have eaten eaten

1  2

2.2

4  8

of the pizza. The fraction

of the pizza, but you also know that you have 4  8

is equivalent to the fraction

1  ; 2

that is, they

both have the same value. The mathematical process we use to rewrite

4  8

as

1  2

is

called reducing to lowest terms. Before we look at that process, we need to define

composite.

B

Factor a number into a product of prime factors.

C D

Write a fraction in lowest terms. Solve applications involving reducing fractions to lowest terms.

some new terms. Here is our first one:

A Prime Numbers

Examples now playing at

MathTV.com/books Definition A prime number is any whole number greater than 1 that has exactly two divisors—–itself and 1. (A number is a divisor of another number if it divides it without a remainder.)

Prime numbers  {2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, . . . } The list goes on indefinitely. Each number in the list has exactly two distinct divisors—itself and 1.

Definition Any whole number greater than 1 that is not a prime number is called a composite number. A composite number always has at least one divisor other than itself and 1.

PRACTICE PROBLEMS

EXAMPLE 1

Identify each of the numbers below as either a prime num-

ber or a composite number. For those that are composite, give two divisors other than the number itself or 1.

a. 43 SOLUTION

b. 12

1. Which of the numbers below are prime numbers, and which are composite? For those that are composite, give two divisors other than the number itself and 1. 37, 39, 51, 59

a. 43 is a prime number, because the only numbers that divide it without a remainder are 43 and 1.

b. 12 is a composite number, because it can be written as 12  4  3, which means that 4 and 3 are divisors of 12. (These are not the only divisors of 12; other divisors are 1, 2, 6, and 12.)

B Factoring Every composite number can be written as the product of prime factors. Let’s look at the composite number 108. We know we can write 108 as 2  54. The

Note

You may have already noticed that the word divisor as we are using it here means the same as the word factor. A divisor and a factor of a number are the same thing. A number can’t be a divisor of another number without also being a factor of it.

number 2 is a prime number, but 54 is not prime. Because 54 can be written as 2  27, we have

Answer 1. See solutions section.

108  2  54  2  2  27

2.2 Prime Numbers, Factors, and Reducing to Lowest Terms

119

120

Chapter 2 Fractions and Mixed Numbers Now the number 27 can be written as 3  9 or 3  3  3 (because 9  3  3), so 8 m m

8

g

108  2  2  3  9

m

8

g

108  2  2  3  3  3 This last line is the number 108 written as the product of prime factors. We can use exponents to rewrite the last line: 108  22  33

EXAMPLE 2

Factor 60 into a product of prime factors.

We begin by writing 60 as 6  10 and continue factoring until all fac-

SOLUTION

tors are prime numbers: m

g

8

60  6  10 8

factors. a. 90 b. 900

g

108  2  2  27

m

2. Factor into a product of prime

108  2  54

88

This process works by writing the original composite number as the product of any two of its factors and then writing any factor that is not prime as the product of any two of its factors. The process is continued until all factors are prime numbers. You do not have to start with the smallest prime factor, as shown in Example 1. No matter which factors you start with you will always end up with the same prime factorization of a number.

m

Note

2325  22  3  5 Notice that if we had started by writing 60 as 3  20, we would have achieved the same result: 60  3  20 g

m

 3  2  10 g

m

8

There are some “shortcuts” to finding the divisors of a number. For instance, if a number ends in 0 or 5, then it is divisible by 5. If a number ends in an even number (0, 2, 4, 6, or 8), then it is divisible by 2. A number is divisible by 3 if the sum of its digits is divisible by 3. For example, 921 is divisible by 3 because the sum of its digits is 9  2  1  12, which is divisible by 3.

8

Note

3225  22  3  5

C Reducing Fractions We can use the method of factoring numbers into prime factors to help reduce fractions to lowest terms. Here is the definition for lowest terms.

Definition A fraction is said to be in lowest terms if the numerator and the denominator have no factors in common other than the number 1.

3. Which of the following fractions are in lowest terms? 1 2 15 9 , , ,  6 8 25 13

EXAMPLE 3

1

1

2

1

3

1

2

3

The fractions 2, 3, 3, 4, 4, 5, 5, 5, and

4  5

are all in lowest

terms, because in each case the numerator and the denominator have no factors other than 1 in common. That is, in each fraction, no number other than 1 divides both the numerator and the denominator exactly (without a remainder).

4. Reduce 1182 to lowest terms by dividing the numerator and the denominator by 6.

EXAMPLE 4

The fraction

6  8

is not written in lowest terms, because the

numerator and the denominator are both divisible by 2. To write

6  8

in lowest

terms, we apply Property 2 from Section 2.1 and divide both the numerator and the denominator by 2: 62 6 3      82 8 4 3

Answers 2. a. 2  32  5 b. 22  32  52 1 9 3. ,  6 13

2 4.  3

The fraction 4 is in lowest terms, because 3 and 4 have no factors in common except the number 1.

121

2.2 Prime Numbers, Factors, and Reducing to Lowest Terms Reducing a fraction to lowest terms is simply a matter of dividing the numerator and the denominator by all the factors they have in common. We know from Property 2 of Section 2.1 that this will produce an equivalent fraction.

EXAMPLE 5

Reduce the fraction

12  15

to lowest terms by first factoring

the numerator and the denominator into prime factors and then dividing both the numerator and the denominator by the factor they have in common.

SOLUTION

The numerator and the denominator factor as follows: 12  2  2  3

and

15  3  5

5 5. Reduce the fraction 1 to lowest 20

terms by first factoring the numerator and the denominator into prime factors and then dividing out the factors they have in common.

The factor they have in common is 3. Property 2 tells us that we can divide both terms of a fraction by 3 to produce an equivalent fraction. So 12 223    15 35

Factor the numerator and the denominator completely

2233   353

Divide by 3

22 4     5 5 The fraction

4  5

is equivalent to

12  15

and is in lowest terms, because the numerator

and the denominator have no factors other than 1 in common. We can shorten the work involved in reducing fractions to lowest terms by using a slash to indicate division. For example, we can write the above problem as: 12 22 3 4        15 3 5 5 So long as we understand that the slashes through the 3’s indicate that we have

6. Reduce to lowest terms. 30 300 a.  b.  35

divided both the numerator and the denominator by 3, we can use this notation.

D Applications EXAMPLE 6

Laura is having a party. She puts 4 six-packs of soda in a

cooler for her guests. At the end of the party she finds that only 4 sodas have been consumed. What fraction of the sodas are left? Write your answer in lowest terms.

SOLUTION

She had 4 six-packs of soda, which is 4(6)  24 sodas. Only 4 were

consumed at the party, so 20 are left. The fraction of sodas left is 20  24 Factoring 20 and 24 completely and then dividing out both the factors they have in common gives us

Note

The slashes in Example 6 indicate that we have divided both the numerator and the denominator by 2  2, which is equal to 4. With some fractions it is apparent at the start what number divides the numerator and the denominator. For instance, you may have recognized that both 20 and 24 in Example 6 are divisible by 4. We can divide both terms by 4 without factoring first, just as we did in Section 2.1. Property 2 guarantees that dividing both terms of a fraction by 4 will produce an equivalent fraction: 20 5 20  4      24  4 24 6

 2 25 20 5       2 223 24 6

EXAMPLE 7 SOLUTION

6 Reduce  to lowest terms. 42 We begin by factoring both terms. We then divide through by any

350

7. Reduce to lowest terms. 8 72

a. 

16 144

b. 

factors common to both terms:  2 3 1 6        2 37 7 42

Answers 3 4

6 7

5.  6. Both are .

122

Chapter 2 Fractions and Mixed Numbers We must be careful in a problem like this to remember that the slashes indicate division. They are used to indicate that we have divided both the numerator and the denominator by 2  3  6. The result of dividing the numerator 6 by 2  3 is 1. It is a very common mistake to call the numerator 0 instead of 1 or to leave the numerator out of the answer.

Reduce each fraction to lowest terms. 5 8.  50

EXAMPLE 8

1   10

EXAMPLE 9

120 25

9. 

 2 21 4 Reduce to lowest terms:     2 225 40

105  3 57 Reduce to lowest terms:    30 5 23  7   2

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. A. What is a prime number? B. Why is the number 22 a composite number? C. Factor 120 into a product of prime factors. D. What is meant by the phrase “a fraction in lowest possible terms”?

Answers 1 9

1 10

24 5

7. Both are . 8.  9. 

2.2 Problem Set

123

Problem Set 2.2 A Identify each of the numbers below as either a prime number or a composite number. For those that are composite, give at least one divisor (factor) other than the number itself or the number 1. [Example 1]

1. 11

2. 23

3. 105

4. 41

5. 81

6. 50

7. 13

8. 219

B Factor each of the following into a product of prime factors. [Example 2] 9. 12

10. 8

11. 81

12. 210

13. 215

14. 75

15. 15

16. 42

C Reduce each fraction to lowest terms. [Examples 4, 5, 7–11] 3 6

19. 

22. 

6 10

26. 

36 60

30. 

12 84

31. 

60 36

35. 

38. 

45 75

66 84

255 285

47. 

5 10

18. 

21. 

8 10

25. 

42 66

29. 

14 98

42 30

34. 

110 70

17. 

33. 

37. 

96

41.  108

102 114

45. 

42. 

46. 

4 6

20. 

23. 

36 20

24. 

27. 

24 40

28. 

70 90

32. 

18 90

36. 

39. 

180 108

40. 

43. 

126 165

44. 

294 693

48. 

4 10

32 12

50 75

80 90

150 210

105 30

210 462

273 385

124

Chapter 2 Fractions and Mixed Numbers

49. Reduce each fraction to lowest terms. 6 51

a. 

6 52

6 54

b. 

c. 

50. Reduce each fraction to lowest terms. 6 56

e. 

6 57

6 d.  90

9 e.  90

d. 

6 42

a. 

51. Reduce each fraction to lowest terms. 2 a.  90

3 b.  90

5 c.  90

6 44

6 45

b. 

6 46

c. 

d. 

6 48

e. 

52. Reduce each fraction to lowest terms. 3 105

a. 

5 105

7 105

b. 

c. 

15 105

d. 

21 105

e. 

53. The answer to each problem below is wrong. Give the correct answer. 5 15

 5 3 5

0 3

5 6

a.     

3 2 4 2

3 4

b.     

6 30

 2 3  2 35

4 12

 2 2  2 23

c.     5

54. The answer to each problem below is wrong. Give the correct answer. 10 20

7 3 17   3

7 17

9 36

a.     

 3 3 22 3 3

6

15

9

21

55. Which of the fractions 8, 2 , , and 2 does not reduce 0 16 8 to

0 4

b.     

3 ? 4

c.     3

4

10

8

6

56. Which of the fractions 9, 1 , , and 1 do not reduce to 5 12 2 2 ? 3

The number line below extends from 0 to 2, with the segment from 0 to 1 and the segment from 1 to 2 each divided into 8 equal parts. Locate each of the following numbers on this number line. 1 2 4 2 4 8

3 6 12 2 4 8

8 16

57. , , , and 

24 16

5 10 4 8

58. , , , and 

0

20 16

1 2 4 8

59. , , and 

1

4 16

60. , , and 

2

2.2 Problem Set

D

Applying the Concepts

125

[Example 6]

61. Tower Heights The Eiffel Tower is 1,060 feet tall and the

62. Car Insurance The chart below shows the annual cost of

Stratosphere Tower in Las Vegas is 1,150 feet tall. Write

auto insurance for some major U.S. cities. Write the

the height of the Eiffel tower over the height of the

price of auto insurance in Los Angeles over the price of

Stratosphere Tower and then reduce to lowest terms.

insurance in Detroit and then reduce to lowest terms.

Priciest Cities for Auto Insurance Detroit

$5,894

Philadelphia

$4,440

Newark, N.J.

$3,977

Los Angeles

$3,430

New York City

$3,303 0

$1000

$2000

$3000

$4000

$5000

$6000

Source: Runzheimer International

63. Hours and Minutes There are 60 minutes in 1 hour. What

64. Final Exam Suppose 33 people took the final exam in a

fraction of an hour is 20 minutes? Write your answer in

math class. If 11 people got an A on the final exam,

lowest terms.

what fraction of the students did not get an A on the exam? Write your answer in lowest terms.

65. Driving Distractions Many of us focus our attention on

66. Watching Television According to the U.S. Census Bureau,

things other than driving when we are behind the

it is estimated that the average person watches 4 hours

wheel of our car. In a survey of 150 drivers, it was

of TV each day. Represent the number of hours of TV

noted that 48 drivers spend time reading or writing

watched each day as a fraction in lowest terms.

while they are driving. Represent the number of drivers who spend time reading or writing while driving as a fraction in lowest terms.

67. Hurricanes Over a recent five-year period, 9 hurricanes

68. Gasoline Tax Suppose a gallon of regular gas costs

struck the mainland of the United States. Three of these

$3.99, and 54 cents of this goes to pay state gas taxes.

hurricanes were classified as a category 3, 4 or 5. Rep-

What fractional part of the cost of a gallon of gas goes

resent the number of major hurricanes that struck the

to state taxes? Write your answer in lowest terms.

mainland U.S. over this time period as a fraction in lowest terms.

69. On-Time Record A random check of Delta airline flights

70. Internet Users Based on the most recent data available,

for the past month showed that of the 350 flights sched-

there are approximately 1,320,000,000 Internet users in

uled 185 left on time. Represent the number of on time

the world. North America makes up about 240,000,000

flights as a fraction in lowest terms.

of this total. Represent the number of Internet users in North America as a fraction of the total expressed in lowest terms.

126

Chapter 2 Fractions and Mixed Numbers

Nutrition The nutrition labels below are from two different granola bars. GRANOLA BAR 1

71. What fraction of the calories in Bar 1 comes from fat?

72. What fraction of the calories in Bar 2

Nutrition Facts

Nutrition Facts

Serving Size 2 bars (47g) Servings Per Container: 6

Serving Size 1 bar (21g) Servings Per Container: 8

Amount Per Serving

Amount Per Serving Calories from fat 70

Calories 210

comes from fat?

% Daily Value* 12%

Total Fat 8g

73. For Bar 1, what fraction of the total fat is from saturated fat?

GRANOLA BAR 2

Total Fat 1.5g

% Daily Value* 2%

5%

Saturated Fat 0g Cholesterol 0mg

0%

0%

Sodium 150mg

6%

Sodium 60mg

3%

Total Carbohydrate 16g Fiber 1g

5%

11% 10%

Sugars 12g

Bar 1 is from sugar?

Calories from fat 15

Saturated Fat 1g Cholesterol 0mg Total Carbohydrate 32g Fiber 2g

74. What fraction of the total carbohydrates in

Calories 80

Protein 4g

Protein 2g

*Percent Daily Values are based on a 2,000 calorie diet. Your daily values may be higher or lower depending on your calorie needs.

*Percent Daily Values are based on a 2,000 calorie diet. Your daily values may be higher or lower depending on your calorie needs.

Multiply.

75. 1  3  1

76. 2  4  5

77. 3  5  3

78. 1  4  1

79. 5  5  1

80. 6  6  2

Factor into prime factors.

82. 72

83. 15  4

84. 8  9

86. 42

87. 52

88. 62

Expand and multiply.

85. 32

4%

Sugars 5g

Getting Ready for the Next Section

81. 60

0%

Maintaining Your Skills Simplify.

89. 16  8  4

90. 16  4  8

91. 24  14  8

92. 24  16  6

93. 36  6  12

94. 36  9  20

95. 48  12  17

96. 48  13  15

Multiplication with Fractions, and the Area of a Triangle Introduction . . . A recipe calls for

3  4

cup of flour. If you are making only

1  2

the recipe, how much

flour do you use? This question can be answered by multiplying

1  2

3

2.3 Objectives A Multiply fractions. B Find the area of a triangle.

and 4. Here is

the problem written in symbols: 1 3 3      2 4 8

Examples now playing at

MathTV.com/books

As you can see from this example, to multiply two fractions, we multiply the numerators and then multiply the denominators. We begin this section with the rule for multiplication of fractions.

Note

You may wonder why we did not divide the amount needed by 2. Dividing by 2 is the same as multiplying by 1.

A Multiplying Fractions

2

Rule The product of two fractions is the fraction whose numerator is the product of the two numerators and whose denominator is the product of the two denominators. We can write this rule in symbols as follows: If a, b, c, and d represent any numbers and b and d are not zero, then

a c ac      b d bd

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

3 2 Multiply:    5 7 Using our rule for multiplication, we multiply the numerators and

2 5 3 9

1. Multiply:   

multiply the denominators: 3 2 32 6          5 7 57 35 3

2

6

The product of 5 and 7 is the fraction 3 . The numerator 6 is the product of 3 and 5 2, and the denominator 35 is the product of 5 and 7.

EXAMPLE 2 SOLUTION

3 Multiply:   5 8 The number 5 can be written as

2 5

2. Multiply:   7 5  . 1

That is, 5 can be considered a

fraction with numerator 5 and denominator 1. Writing 5 this way enables us to apply the rule for multiplying fractions. 3 3 5   5     8 8 1 35   81 15   8

Answers 10 27

14 5

1.  2. 

2.3 Multiplication with Fractions, and the Area of a Triangle

127

128

Chapter 2 Fractions and Mixed Numbers

1 4 3 5



1 3



3. Multiply:    

EXAMPLE 3 SOLUTION

1 3 1 Multiply:     2 4 5 We find the product inside the parentheses first and then multiply





1

the result by 2: 1 3 1 1 31         2 4 5 2 45





  1 3     2  20  13 3      2  20 40

The properties of multiplication that we developed in Chapter 1 for whole numbers apply to fractions as well. That is, if a, b, and c are fractions, then abba a  (b  c)  (a  b)  c

Multiplication with fractions is commutative Multiplication with fractions is associative

To demonstrate the associative property for fractions, let’s do Example 3 again, but this time we will apply the associative property first:



 



1 3 1 1 3 1           2 4 5 2 4 5

Associative property

13 1      24 5





 

3 1     8 5 31 3      85 40 The result is identical to that of Example 3. Here is another example that involves the associative property. Problems like this will be useful when we solve equations.

Answers 4 45

3. 

129

2.3 Multiplication with Fractions, and the Area of a Triangle The answers to all the examples so far in this section have been in lowest terms. Let’s see what happens when we multiply two fractions to get a product that is not in lowest terms.

EXAMPLE 4 SOLUTION

15 4 Multiply:    8 9 Multiplying the numerators and multiplying the denominators, we

have 15 4 15  4        8 9 89

4. Multiply. 12 5 25 6 12 50 b.    25 60

a.   

60   72 60  , 72

The product is

which can be reduced to lowest terms by factoring 60 and 72

and then dividing out any factors they have in common: 60  2 2 35     72  2 22 33 5   6 We can actually save ourselves some time by factoring before we multiply. Here’s how it is done: 15 4 15  4        8 9 89 (3  5)  (2  2)   (2  2  2)  (3  3)  2 2 35    2 22 33 5   6 The result is the same in both cases. Reducing to lowest terms before we actually multiply takes less time. Here are some additional examples.

EXAMPLE 5 SOLUTION

9 8 Multiply:   2 18

 

9 8 98     2  18 2 18

 

(3  3)  (2  2  2)   2  (2  3  3)  3 2 22 3    2 2 3 3 2   1 2

5. Multiply. 8 9 3 24 8 90 b.    30 24

a.   

Note

2

Although 1 is in lowest terms, it is still simpler to write the answer as just 2. We will always do this when the denominator is the number 1.

Answers 2 5

4. Both are  5. Both are 1

130

Chapter 2 Fractions and Mixed Numbers

3 4

8 3

1 6

EXAMPLE 6

6. Multiply:     

2 3

6 5

2 6 5 Multiply:      3 5 8 265 358

5 8

SOLUTION        2  (2  3)  5   3  5  (2  2  2)  2 2 3 5    3 5 2 22 1   2 In Chapter 1 we did some work with exponents. We can extend our work with Apply the definition of exponents, and then multiply. 2

EXAMPLE 7

3

7. 

exponents to include fractions, as the following examples indicate.

2

SOLUTION

 

2

 

2

3 Expand and multiply:  4

 4    4  4  3

3

2

3

33   44 9   16 3

EXAMPLE 8

1 2 3 9  

8

4 2 b.  3

2

8. a.   

SOLUTION

 6  5

2

5 Expand and multiply:  6

1 5 5 1         2 6 6 2 551   662 25   72

The word of used in connection with fractions indicates multiplication. If we 1

2

want to find 2 of 3, then what we do is multiply 2 1 3 2 3 b. Find  of 15. 5

EXAMPLE 9

9. a. Find  of .

SOLUTION

1  2

2

and 3.

1 2 Find  of  . 2 3

Knowing the word of, as used here, indicates multiplication, we

have 2 1 2 1  of      2 3 2 3 1 2 1      23 3 This seems to make sense. Logically, 1 2

0 Answers 1 3

4 9

9 32

1 3

6.  7.  8. a.  b.  1 9. a.  b. 9 3

of

1  2

2

1

of 3 should be 3, as Figure 1 shows.

2 3

1 3

2 3

2 3

FIGURE 1

1

131

2.3 Multiplication with Fractions, and the Area of a Triangle

EXAMPLE 10 SOLUTION

3 What is  of 12? 4

2 3 2 b. What is  of 120? 3

10. a. What is  of 12?

Again, of means multiply. 3 3  of 12   (12) 4 4

Note

As you become familiar with multiplying fractions, you may notice shortcuts that reduce the number of steps in the problems. It’s okay to use these shortcuts if you understand why they work and are consistently getting correct answers. If you are using shortcuts and not consistently getting correct answers, then go back to showing all the work until you completely understand the process.

 

3 12    4 1 3  12   41

3 2 23    2 21 9   9 1

B The Area of a Triangle FACTS FROM GEOMETRY The Area of a Triangle The formula for the area of a triangle is one application of multiplication with fractions. Figure 2 shows a triangle with base b and height h. Below the triangle is the formula for its area. As you can see, it is a product containing the 1

fraction 2.

h

11. Find the area of the triangle

b 1 Area = 2 (base)(height) 1 A = 2 bh FIGURE 2 The area of a triangle

EXAMPLE 11

below.

10 in. Find the area of the triangle in Figure 3.

7 in.

7 in.

10 in. FIGURE 3 A triangle with base 10 inches and height 7 inches

SOLUTION

Applying the formula for the area of a triangle, we have 1 1 A   bh    10  7  5  7  35 in2 2 2

Note

How did we get in2 as the final units in Example 14? In this

problem 1 A  bh 2 1    10 inches  7 inches 2  5 in.  7 in.  35 in2

Answers 10. a. 8 b. 80 11. 35 in2

132

Chapter 2 Fractions and Mixed Numbers

12. Find the total area enclosed by

EXAMPLE 12

Find the area of the figure in Figure 4.

the figure.

4 ft

4 ft 3 ft

4 ft 6 ft

8 ft

4 ft 10 ft

9 ft

6 ft FIGURE 4

Note

This is just a reminder about unit notation. In Example 11 we wrote our final units as in2 but could have just as easily written them as sq in. In Example 12 we wrote our final units as sq ft but could have just as easily written them as ft2.

SOLUTION

We divide the figure into three parts and then find the area of each

part (see Figure 5). The area of the whole figure is the sum of the areas of its parts.

4 ft 3 ft A  12  6  5  15 sq ft

A34  12 sq ft

A59  45 sq ft

5 ft 9 ft

6 ft FIGURE 5 Total area  12  45  15  72 sq ft

STUDY SKILLS Be Resilient Don’t let setbacks keep you from your goals. You want to put yourself on the road to becoming someone who can succeed in this class or any class in college. Failing a test or quiz or having a difficult time on some topics is normal. No one goes through college without some setbacks. A low grade on a test or quiz is simply a signal that some reevaluation of your study habits needs to take place.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 3 2 1. When we multiply the fractions  and , the numerator in the answer 5 7 will be what number? 1 2 2. When we ask for  of , are we asking for an addition problem or a 2 3 multiplication problem? Answer

15. 34 ft2

3. True or false? Reducing to lowest terms before you multiply two fractions will give the same answer as if you were to reduce after you multiply. 4. Write the formula for the area of a triangle with base x and height y.

133

2.3 Problem Set

Problem Set 2.3 A Find each of the following products. (Multiply.) [Examples 1–4, 6–9] 2 3

5 6

4 5

7 4

1 2

2.   

3.   

3 4

8.   5

2 3

9.  

7.   9

2 5

3 5

4 5

13.     

1 4

3 4

3 4

14.     

3 5

7 4

1.   

6 7

6

3 2

5 2

4 7

4.   

7

2 9

2

4 3

5 3

9

10.  

7 2

15.     

5 3

3 5

1 2

1 3

1 4

11.     

19.

First Number x

Second Number y

1  2

Their Product xy

7 3

16.     

18.

First Number x

Second Number y

2  3

12

1  2

2  3

3  4

12

1  3

3  4

4  5

12

1  4

5  a

a  6

12

1  6

First Number x

Second Number y

First Number x

Second Number y

1  2

30

1  3

3  5

1  5

30

3  5

5  7

1  6

30

5  7

7  9

1  15

30

7  b

b  11

Their Product xy

20.

7 4

2 3

4 5

1 3

12.     

A Complete the following tables. 17.

4 7

6.   

5.   

Their Product xy

Their Product xy

134

Chapter 2 Fractions and Mixed Numbers

A Multiply each of the following. Be sure all answers are written in lowest terms. [Examples 1–3, 4–6] 135 16

4 3

9 20

21.   

1 3

1 5

25.  (3)

72 35

2 45

22.   

26.  (5)

55 108

7 110

29.     

32 27

23.   12

3 4

24.   20

3 4

2 5

28.   15

3 5

27.   20

72 49

1 40

30.     

A Expand and simplify each of the following. [Examples 7, 8]

3

32. 

2

36. 

2

31. 

1

35. 

3

2

3

37. 

5

 4 3

2

2

2

2

3 1

2

2

3 2

2

2

34. 

1

41. 

2

3

38. 

3

3

42. 

2

44.   9    4

A [Examples 8, 9] 3 8

45. Find  of 64.

1 3

47. What is  of the sum of 8 and 4?

1 2

3 4

49. Find  of  of 24.

2 3

46. Find  of 18.

3 5

48. What is  of the sum of 8 and 7?

3 5

3

 8  3

2

2 1

2

 5

3

 2  5

12 15

40.   

43.   8    9

 7

2

3

2

6

8 9

39.   

1

33. 

1

2

4

5 3

2

1 3

50. Find  of  of 15.

2

4

2

135

2.3 Problem Set Find the mistakes in Problems 51 and 52. Correct the right-hand side of each one. 1 2

3 5

2 7

4 10

3 5

5 35

51.     

52.     

53. a. Complete the following table.

54. a. Complete the following table.

Number x

Square x2

Number x

Square x2

1  2

1 2

1  3

3

1  4

4

1  5

5 6

1  6

7

1  7

8

b. Using the results of part a, fill in the blank in the fol-

1  8

lowing statement:

b. Using the results of part a, fill in the blank in the folFor numbers larger than 1, the square of the number is

lowing statement:

than the number. For numbers between 0 and 1, the square of the number is

than the number.

B [Examples 11, 12] 55. Find the area of the triangle with base 19 inches and

height 8 inches.

height 14 inches.

4

2

57. The base of a triangle is 3 feet and the height is 3 feet. Find the area.

56. Find the area of the triangle with base 13 inches and

8

14

58. The base of a triangle is 7 feet and the height is 5 feet. Find the area.

136

Chapter 2 Fractions and Mixed Numbers

Find the area of each figure.

59.

60.

7 mi

6 mi

3 yd 3 mi

9 mi

2 yd

61.

62.

12 in.

5 in.

10 in. 8 in.

4 in.

5 in. 6 in.

20 in.

Applying the Concepts 63. Rainfall The chart shows the average rainfall for Death

64. Rainfall The chart shows the average rainfall for Death

Valley in the given months. Use this chart to answer

Valley in the given months. Use this chart to answer

the questions below.

the questions below.

Death Valley Rainfall

Death Valley Rainfall 1 2

1 4

1 4

1 4

0

Jan

Mar

1 4 1 10

1 10

May

Jul

1 4

1 4

1 3

3 25

0

Sep

Feb

Nov

a. How many inches of rain is 5 times the average for January?

b. How many inches of rain is 7 times the average for May?

c. How many inches of rain is 12 times the average for September?

inches

measured in inches

1 2

Apr

1 20

1 10

Jun

Aug

1 4

1 4

Oct

Dec

a. How many inches of rain is 6 times the average for February?

b. How many inches of rain is 5 times the average for April?

c. How many inches of rain is 8 times the average for October?

2.3 Problem Set 65. Hot Air Balloon Aerostar International makes a hot air

137

66. Bicycle Safety The National Safe Kids Campaign and

balloon called the Rally 105 that has a volume of

Bell Sports sponsored a study that surveyed 8,159 chil-

105,400 cubic feet. Another balloon, the Rally 126, was

dren ages 5 to 14 who were riding bicycles. Approxi-

6

2

designed with a volume that is approximately 5 the

mately 5 of the children were wearing helmets, and of

volume of the Rally 105. Find the volume of the Rally

those, only 20 were wearing the helmets correctly.

126 to the nearest hundred cubic feet.

About how many of the children were wearing helmets

13

correctly?

67. Health Care According to a study reported on MSNBC,

3

68. Working Students Studies indicate that approximately 4

almost one-third of the people diagnosed with diabetes

of all undergraduate college students work while at-

don’t seek proper medical care. If there are 12 million

tending school. A local community college has a stu-

Americans with diabetes, about how many of them are

dent enrollment of 8,500 students. How many of these

seeking proper medical care?

students work while attending college?

69. Cigarette Tax In a recent survey of 1,410 adults, it was determined that

3  5

70. Shared Rent You and three friends decide to rent an

of those surveyed favored raising the

apartment for the academic year rather than to live in

tax on cigarettes as a way to discourage young people

the dorms. The monthly rent is $1250. If you and your

from smoking. What number of adults believes that

friends split the rent equally, what is your share of the

this would reduce the number of young people who

monthly rent?

smoke?

71. Importing Oil According to the U.S. Department of En-

72. Improving Your Quantitative Literacy MSNBC reported that

ergy, we imported approximately 8,340,000 barrels of

at least three-fourths of the 55 companies that adver-

oil in November 2007, which represents a typical

tise nationally on television will cut spending on com-

1

month. We import a little over 5 of our oil from Canada,

mercials because of electronics that let viewers record

of our oil from Venezuela, and less approximately 2 0

programs and edit out commercials. Does this mean at

of our oil from Iraq. Determine the amount of than 1 0

least 41, or at least 42, of the companies will cut spend-

oil we imported from each of these countries.

ing on commercials?

3

1

Geometric Sequences Recall that a geometric sequence is a sequence in which each term comes from the previous term by 1

1

1

multiplying by the same number each time. For example, the sequence 1, 2, 4, 8, . . . is a geometric sequence in which each term is found by multiplying the previous term by 1

1

1 . 2

By observing this fact, we know that the next term in the sequence will

1

be 8  2  16. Find the next number in each of the geometric sequences below. 1 1 3 9

73. 1, , , . . .

1 1 4 16

74. 1, , , . . .

3 2

2 4 3 9

75. , 1, , , . . .

2 3

3 9 2 4

76. , 1, , , . . .

138

Chapter 2 Fractions and Mixed Numbers

Estimating For each problem below, mentally estimate which of the numbers 0, 1, 2, or 3 is closest to the answer. Make your estimate without using pencil and paper or a calculator. 11 5

19 20

3 5

77.   

16 5

1 20

78.   

23 24

9 8

79.   

31 32

80.   

Getting Ready for the Next Section In the next section we will do division with fractions. As you already know, division and multiplication are closely related. These review problems are intended to let you see more of the relationship between multiplication and division. Perform the indicated operations. 1 4

81. 8  4

1 3

84. 15  

82. 8  

83. 15  3

85. 18  6

86. 18  

1 6

For each number below, find a number to multiply it by to obtain 1. 3 4

87. 

9 5

1 3

88. 

89. 

1 4

90. 

91. 7

92. 2

Maintaining Your Skills Simplify.

93. 20  2  10

94. 40  4  5

95. 24  8  3

96. 24  4  6

97. 36  6  3

98. 36  9  2

99. 48  12  2

100. 48  8  3

Division with Fractions Introduction . . . A few years ago our 4-H club was making blankets to keep their lambs clean at 3

2.4 Objectives A Divide fractions. B Simplify order of operation

problems involving division of fractions.

the county fair. Each blanket required 4 yard of material. We had 9 yards of material left over from the year before. To see how many blankets we could make, we 3

divided 9 by 4. The result was 12, meaning that we could make 12 lamb blankets for the fair.

C

Solve application problems involving division of fractions.

Before we define division with fractions, we must first introduce the idea of reciprocals. Look at the following multiplication problems: 3 4 12       1 4 3 12

7 8 56        1 8 7 56

Examples now playing at

MathTV.com/books

In each case the product is 1. Whenever the product of two numbers is 1, we say the two numbers are reciprocals.

Definition Two numbers whose product is 1 are said to be reciprocals. In symbols, the b a reciprocal of  is , because a b ab ab a b         1 ba ab b a

(a  0, b  0)

Every number has a reciprocal except 0. The reason that 0 does not have a reciprocal is because the product of any number with 0 is 0. It can never be 1. Reciprocals of whole numbers are fractions with 1 as the numerator. For exam1

ple, the reciprocal of 5 is 5, because 1 5 1 5 5          1 5 1 5 5 Table 1 lists some numbers and their reciprocals. TABLE 1

Number

Reciprocal

Reason

3  4

4  3

3 4 12 Because       1 4 3 12

9  5

5  9

9 5 45 Because       1 5 9 45

1  3

3

1 1 3 3 Because   3        1 3 3 1 3

7

1  7

1 7 1 7 Because 7          1 7 1 7 7

 

A Dividing Fractions Division with fractions is accomplished by using reciprocals. More specifically, we can define division by a fraction to be the same as multiplication by its reciprocal. Here is the precise definition:

Definition If a, b, c, and d are numbers and b, c, and d are all not equal to 0, then

a c a d        b d b c

2.4 Division with Fractions

Note

Defining division to be the same as multiplication by the reciprocal does make sense. If we divide 6 by 2, we get 3. On the other hand, if we multiply 6 by 12 (the reciprocal of 2), we also get 3. Whether we divide by 2 or multiply by 21, we get the same result.

139

140

Chapter 2 Fractions and Mixed Numbers c This definition states that dividing by the fraction  is exactly the same as muld d tiplying by its reciprocal . Because we developed the rule for multiplying fracc tions in Section 2.3, we do not need a new rule for division. We simply replace the divisor by its reciprocal and multiply. Here are some examples to illustrate the procedure.

PRACTICE PROBLEMS

EXAMPLE 1

1. Divide. 1 1 a.   

3 6 1 1 30 60

SOLUTION

b.   

1 1 Divide:    2 4 1 The divisor is 4, and its reciprocal is

4  . 1

Applying the definition of

division for fractions, we have 1 1 1 4        2 4 2 1 14   21 1 22   2 1 2   1 2 The quotient of

1  2

and

1  4

is 2. Or,

1  4

“goes into”

1  2

two times. Logically, our defini-

tion for division of fractions seems to be giving us answers that are consistent 1

with what we know about fractions from previous experience. Because 2 times 4 2

1

1

is 4 or 2, it seems logical that 2 divided by 5 9

1  4

should be 2.

EXAMPLE 2

10 3

2. Divide:   

SOLUTION

3 9 Divide:    8 4 9 4 Dividing by 4 is the same as multiplying by its reciprocal, which is 9: 3 9 3 4        8 4 8 9  3 2 2    2 223 3 1   6 3

9

1

The quotient of 8 and 4 is 6.

EXAMPLE 3

3. Divide. 3 a.   3 4 3 b.   3 5 3 c.   3 7

SOLUTION

2 Divide:   2 3 1 The reciprocal of 2 is 2. Applying the definition for division of frac-

tions, we have 2 2 1   2     3 3 2 1 2   3 2 1   3

EXAMPLE 4

1 5

4. Divide: 4  

SOLUTION

Answers 1 1. Both are 2 2. 

6 1 1 1 3. a.  b.  c.  4 5 7

 

1 Divide: 2   3 1 We replace 3 by its reciprocal, which is 3, and multiply:

 

1 2    2(3) 3 4. 20

6

141

2.4 Division with Fractions Here are some further examples of division with fractions. Notice in each case that the first step is the only new part of the process.

EXAMPLE 5 SOLUTION

16 4 Divide:    9 27

16 4 4 9        9 27 27 16

Find each quotient. 10 5 42 32 15 30 b.    32 42

5. a.   

 9 4   39 4 4 1   12 In Example 5 we did not factor the numerator and the denominator completely in order to reduce to lowest terms because, as you have probably already noticed, it is not necessary to do so. We need to factor only enough to show what numbers are common to the numerator and the denominator. If we factored completely in the second step, it would look like this:  2 2 3 3    3 33 2 222 1   12 The result is the same in both cases. From now on we will factor numerators and denominators only enough to show the factors we are dividing out.

EXAMPLE 6 SOLUTION

16 Divide:   8 35

16 16 1    8      35 35 8

12 25 24 b.   6 25

6. a.   6

28 1   35  8  2   35

EXAMPLE 7 SOLUTION

 

3 Divide: 27   2

 

 

3 2 27    27   2 3

92 3   3 

4 3 4 b. 12   5 4 c. 12   7

7. a. 12  

 18

Answers 21 2 4 5. Both are  6. a.  b.  32

7. a. 9 b. 15 c. 21

25

25

142

Chapter 2 Fractions and Mixed Numbers

B Fractions and the Order of Operations The next two examples combine what we have learned about division of fractions with the rule for order of operations. 8. The quotient of 45 and 81 is increased by 8. What number results?

EXAMPLE 8

The quotient of

8  3

and

1  6

is increased by 5. What number

results?

SOLUTION

Translating to symbols, we have 8 1 8 6     5      5 3 6 3 1  16  5  21

EXAMPLE 9

9. Simplify: 3 18   5

 

2

2  48   5

 

2

SOLUTION

 

 

4 2 5 2 Simplify: 32    75   3 2 According to the rule for order of operations, we must first evaluate

the numbers with exponents, then divide, and finally, add.

 

4 32   3

2

 

5  75   2

2

16 25  32    75   9 4 9 4  32    75   16 25  18  12  30

C Applications 10. How many blankets can the 4-H club make with 12 yards of material?

EXAMPLE 10

A 4-H club is making blankets to keep their lambs clean at

the county fair. If each blanket requires

3  4

yard of material, how many blankets

can they make from 9 yards of material?

SOLUTION

3

To answer this question we must divide 9 by 4. 3 4 9    9   4 3 34  12

They can make 12 blankets from the 9 yards of material.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. What do we call two numbers whose product is 1? 3

3

3

2. True or false? The quotient of 5 and 8 is the same as the product of 5 8 and 3. 3. How are multiplication and division of fractions related? 19

4. Dividing by 9 is the same as multiplying by what number? Answers 8. 18 9. 350 10. 16 blankets

2.4 Problem Set

Problem Set 2.4 A Find the quotient in each case by replacing the divisor by its reciprocal and multiplying. [Examples 1–7] 3 4

1 5

2.   

1 3

5. 6  

2 3

6. 8  

9.   2

3 4

10.   2

11.   

7 8

14.   

4 3

15.   

9 16

3 4

16.   

25 24

19.   

13 28

39 14

20.   

1.   

3.   

2 3

3 4

7. 20  

8 7

40 69

7 8

3 4

15 36

17.   

18.   

27 196

22.   

9 392

16 135

21.   

3 4

26. 12  

1 2

30. 12    7

29.     6

35 110

2 45

4 3

25. 6  

80 63

16 27

33.     

1 2

5 8

1 4

4.   

1 8

1 10

3 5

13.   

25 46

1 2

8. 16  

7 8

4 3

4 3

12.   

25 36

5 6

28 125

25 18

24.   6

4 3

28.   12

30 27

23.   5

4 3

27.   6

6 7

31.     

2 3

20 72

3 4

42 18

5 2

4 3

5 8

7 6

32. 4    7

20 16

34.     

143

144

Chapter 2 Fractions and Mixed Numbers

B Simplify each expression as much as possible. [Examples 8, 9]

2 1

35. 10  

1

36. 12  

7

18 35

6

3 8

1 10

11 24

5

13 14

6 5

2

7

2

3

3 2

9 7

2

44. 18    49  

 11  8

2

2

2

 11  9

46. 64    81  

3 8

5 8

47. What is the quotient of  and ?

3 5

49. If the quotient of 18 and  is increased by 10, what

51. Show that multiplying 3 by 5 is the same as dividing 3 1 by . 5

13 42

4

2

45. 100    200  

number results?

1 16

42. 15    

43. 24    25  

5

2

40.     4

41. 10    

2

8

38.   

39.     5

11 12

2

 11 

48 55

2

37.   

4 5

4

2

2

4 5

16 25

48. Find the quotient of  and .

5 3

50. If the quotient of 50 and  is increased by 8, what number results?

1 2

52. Show that multiplying 8 by  is the same as dividing 8 by 2.

145

2.4 Problem Set

C

Applying the Concepts

[Example 10]

5

53. Pyramids The Luxor Hotel in Las Vegas is 7 the original

3

54. Skyscrapers The Bloomberg tower in New York City is 5

height of the Great Pyramid of Giza. If the hotel is 350

the height of the Sears Tower. How tall is the

feet tall, what was the original height of the Great Pyra-

Bloomberg tower?

mid of Giza?

Such Great Heights Taipei 101 Taipei, Taiwan

Petronas Tower 1 & 2 Kuala Lumpur, Malaysia

1,483 ft Sears Tower Chicago, USA

1,670 ft

1,450 ft

Source: www.tenmojo.com

6

55. Sewing If 7 yard of material is needed to make a blan-

56. Manufacturing A clothing manufacturer is making 3

ket, how many blankets can be made from 12 yards of

scarves that require 8 yard of material each. How many

material?

can be made from 27 yards of material?

1

57. Cooking A man is making cookies from a recipe that calls for

3  4

58. Cooking A cake recipe calls for 2 cup of sugar. If the

teaspoon of oil. If the only measuring spoon 1

he can find is a 8 teaspoon, how many of these will he 3

have to fill with oil in order to have a total of 4 tea-

1

only measuring cup available is a 8 cup, how many of these will have to be filled with sugar to make a total of 1  2

cup of sugar?

spoon of oil?

1

59. Cartons of Milk If a small carton of milk holds exactly 2 pint, how many of the

1 -pint 2

cartons can be filled from

2

60. Pieces of Pipe How many pieces of pipe that are 3 foot long must be laid together to make a pipe 16 feet long?

a 14-pint container?

61. Lot Size A land developer wants to subdivide 5 acres of property into lots suitable for building a home. If each 1

lot is to be 4 of an acre in size how many lots can be made?

1

62. House Plans If 8 inch represents 1 ft on a drawing of a new home, determine the dimensions of a bedroom that measures 2 inches by 2 inches on the drawing.

146

Chapter 2 Fractions and Mixed Numbers

Getting Ready for the Next Section Write each fraction as an equivalent fraction with denominator 6. 1 2

1 3

63. 

3 2

64. 

2 3

65. 

66. 

Write each fraction as an equivalent fraction with denominator 12. 1 3

1 2

67. 

2 3

68. 

3 4

69. 

70. 

Write each fraction as an equivalent fraction with denominator 30. 3 7 3 71.  72.  73.  5 15 10

1 6

74. 

Write each fraction as an equivalent fraction with denominator 24. 1 1 1 75.  76.  77.  2 4 6

1 8

78. 

Write each fraction as an equivalent fraction with denominator 36. 1 5 7 79.  80.  81.  4 12 18

1 6

82. 

Maintaining Your Skills 83. Fill in the table by rounding the numbers. Number

84. Fill in the table by rounding the numbers.

Rounded to the Nearest Ten

Hundred

63

747

636

474

363

the following?

b. 10

Rounded to the Nearest Ten

74

85. Estimating The quotient 253  24 is closer to which of a. 5

Number

Thousand

Hundred

86. Estimating The quotient 1,000  47 is closer to which of the following?

c. 15

d. 20

Thousand

a. 5

b. 10

c. 15

d. 20

Addition and Subtraction with Fractions

2.5 Objectives A Add and subtract fractions with the

Introduction . . . Adding and subtracting fractions is actually just another application of the distributive property. The distributive property looks like this: a(b  c)  a(b)  a(c) where a, b, and c may be whole numbers or fractions. We will want to apply this

same denominator.

B

Add and subtract fractions with different denominators.

C

Solve applications involving addition and subtraction of fractions.

property to expressions like 3 2    7 7

Examples now playing at But before we do, we must make one additional observation about fractions. 2

MathTV.com/books

1

The fraction 7 can be written as 2  7, because 1 2 1 2 2        7 1 7 7 Likewise, the fraction

3  7

Note

1

can be written as 3  7, because

1 3 1 3 3        7 1 7 7 a 1 In general, we can say that the fraction  can always be written as a  , because b b a 1 a 1 a        b 1 b b 2  7

To add the fractions

3

and 7, we simply rewrite each of them as we have done

above and apply the distributive property. Here is how it works: 3 1 1 2    2  3  7 7 7 7

Rewrite each fraction

1  (2  3)   7

Apply the distributive property

1 5  7

Add 2 and 3 to get 5

5   7

1 5 Rewrite 5   as  7 7

Most people who have done any work with adding fractions know that you add fractions that have the same denominator by adding their numerators, but not their denominators. However, most people don’t know why this works. The reason why we add numerators but not denominators is because of the distributive property. And that is what the discussion at the left is all about. If you really want to understand addition of fractions, pay close attention to this discussion.

We can visualize the process shown above by using circles that are divided into 7 equal parts:

1 7 1 7

1 7

1 7

1 7

1 7

2 7

The fraction

5  7

is the sum of

1 1 7 7

1 7 1 7

1 7

1 7 3 7

+ 2  7

1 7

1 7 1 7

1 7

=

1 1 7 7 1 7

1 7

1 7

5 7

3

and 7. The steps and diagrams above show why

we add numerators but do not add denominators. Using this example as justification, we can write a rule for adding two fractions that have the same denominator.

2.5 Addition and Subtraction with Fractions

147

148

Chapter 2 Fractions and Mixed Numbers

A Combining Fractions with the Same Denominator Rule To add two fractions that have the same denominator, we add their numerators to get the numerator of the answer. The denominator in the answer is the same denominator as in the original fractions.

What we have here is the sum of the numerators placed over the common denominator. In symbols we have the following:

Addition and Subtraction of Fractions If a, b, and c are numbers, and c is not equal to 0, then a b ab      c c c This rule holds for subtraction as well. That is, a b ab      c c c

PRACTICE PROBLEMS Find the sum or difference. Reduce all answers to lowest terms. 1

3

EXAMPLE 1

 1.  10  10

SOLUTION

a5

3 1 31    8 8 8

EXAMPLE 2

3

 2.  12  12

SOLUTION

3 1 Add:    8 8

Add numerators; keep the same denominator

4   8

The sum of 3 and 1 is 4

1   2

Reduce to lowest terms

a5 3 Subtract:    8 8

a5 3 a53      8 8 8 a2   8

8

EXAMPLE 3

5

 3.  7  7

SOLUTION

5

8

3 93 9      5 5 5

EXAMPLE 4

5

SOLUTION

2

Subtract numerators; keep the same denominator The difference of 9 and 3 is 6

3 2 9 Add:      7 7 7

329 3 2 9        7 7 7 7 14  7

Answers 1.  5

The difference of 5 and 3 is 2

9 3 Subtract:    5 5

6   5

  4.  9  9  9

Combine numerators; keep the same denominator

a8

2.  12

3

3.  7

2 4. 2 As Examples 1–4 indicate, addition and subtraction are simple, straightforward processes when all the fractions have the same denominator.

149

2.5 Addition and Subtraction with Fractions

B The Least Common Denominator or LCD We will now turn our attention to the process of adding fractions that have different denominators. In order to get started, we need the following definition.

Definition The least common denominator (LCD) for a set of denominators is the smallest number that is exactly divisible by each denominator. (Note that, in some books, the least common denominator is also called the least common multiple.) In other words, all the denominators of the fractions involved in a problem must divide into the least common denominator exactly. That is, they divide it without leaving a remainder.

EXAMPLE 5 SOLUTION

5 7 Find the LCD for the fractions  and  . 12 18 The least common denominator for the denominators 12 and 18

5. a. Find the LCD for the fractions: 5 3  and  18 14

must be the smallest number divisible by both 12 and 18. We can factor 12 and 18 completely and then build the LCD from these factors. Factoring 12 and 18 completely gives us 12  2  2  3

b. Find the LCD for the fractions: 5 3  and  36 28

18  2  3  3

Now, if 12 is going to divide the LCD exactly, then the LCD must have factors of 2  2  3. If 18 is to divide it exactly, it must have factors of 2  3  3. We don’t need to repeat the factors that 12 and 18 have in common:



LCD  2  2  3  3  36 m 8 m 8 m

18  2  3  3

m 8 m 8 m

12 divides the LCD

12  2  2  3

18 divides the LCD

The LCD for 12 and 18 is 36. It is the smallest number that is divisible by both 12 and 18; 12 divides it exactly three times, and 18 divides it exactly two times. We can visualize the results in Example 5 with the diagram below. It shows that 36 is the smallest number that both 12 and 18 divide evenly. As you can see, 12 divides 36 exactly 3 times, and 18 divides 36 exactly 2 times.

12

12

18

Note

The ability to find least common denominators is very important in mathematics. The discussion here is a detailed explanation of how to find an LCD.

12 18

36

EXAMPLE 6 SOLUTION

7 5 Add:    12 18 We can add fractions only when they have the same denominators.

In Example 5, we found the LCD for

5  12

and

7  18

to be 36. We change

5  12

and

7  18

to

equivalent fractions that have 36 for a denominator by applying Property 1 for

6. Add. 5 3 18 14 5 3 b.    36 28

a.   

fractions: 53 5 15      12  3 12 36 72 14 7      18 2 18 36

Answer 5. a. 126 b. 252

150

Chapter 2 Fractions and Mixed Numbers 15  36

The fraction

is equivalent to

5  , 12

because it was obtained by multiplying both

the numerator and the denominator by 3. Likewise,

14  36

is equivalent to

7  , 18

be-

cause it was obtained by multiplying the numerator and the denominator by 2. All we have left to do is to add numerators. 15 14 29      36 36 36 The sum of

5  12

and

7  18

is the fraction

29  . 36

Let’s write the complete problem again

step by step. 53 72 5 7        12  3 18  2 12 18

Rewrite each fraction as an equivalent fraction with denominator 36

15 14     36 36 29   36

Add numerators; keep the common denominator

EXAMPLE 7

4 2 15 9 2 4 b. Find the LCD for  and . 27 45

7. a. Find the LCD for  and .

3 1 Find the LCD for  and  . 4 6 We factor 4 and 6 into products of prime factors and build the LCD

SOLUTION

from these factors. 422 623



LCD  2  2  3  12

The LCD is 12. Both denominators divide it exactly; 4 divides 12 exactly 3 times, and 6 divides 12 exactly 2 times. 8. Add.

EXAMPLE 8

2 4 9 15 2 4 b.    27 45

a.   

Note 1 4

1 4

1 4

1 4

1 1 12 12

3

1 12

1 6 1 6

1 12 1 12

1 12 1 12

9 12

33 9 3      43 4 12

1 1 1 12 12 1 12 12

1 12

1 1 1 12 12 12

1 6 1 6 1 6

1 6 1 6

1 1 12 12

=

9  12

3

is equal to the fraction 4, because it was obtained by multiplying

the numerator and the denominator of

1 12

1  6 1 12 1 12

3  4

by 3. Likewise,

2  12

is equivalent to

by 2. To complete the problem we add numerators: 2 11 9      12 12 12

=

1 12 1 12

11 12

Answers 31 31 126 63 22 22 8. a.  b.  45 135

The fraction

1  , 6

because it was obtained by multiplying the numerator and the denominator of

1 1 1 12 12 1 12 12

1 12

12 2 1      62 6 12

2 12

+

1 12 1 12

1

We begin by changing 4 and 6 to equivalent fractions with denominator 12:

+

1 1 1 12 12 1 12 12

1 12

SOLUTION

We can visualize the work in Example 8 using circles and shading:

3 4

1 12 1 12

3 1 Add:    4 6 In Example 7, we found that the LCD for these two fractions is 12.

6. a.  b.  7. a. 45 b. 135

3

1

11

The sum of 4 and 6 is 1 . Here is how the complete problem looks: 2 33 12 3 1        43 62 4 6

Rewrite each fraction as an equivalent fraction with denominator 12

9 2     12 12 11   12

Add numerators; keep the same denominator

151

2.5 Addition and Subtraction with Fractions

EXAMPLE 9 SOLUTION

3 7 Subtract:    15 10 Let’s factor 15 and 10 completely and use these factors to build the

8 25

3 20

9. Subtract:   

LCD:

m

 LCD  2  3  5  30 8 8

m

10  2  5

m 8 m

15 divides the LCD

15  3  5

10 divides the LCD

Changing to equivalent fractions and subtracting, we have 72 33 7 3        15  2 10  3 15 10

Rewrite as equivalent fractions with the LCD for the denominator

9 14     30 30 5   30

Subtract numerators; keep the LCD

1   6

Reduce to lowest terms

As a summary of what we have done so far, and as a guide to working other problems, we now list the steps involved in adding and subtracting fractions with different denominators.

Strategy Adding or Subtracting Any Two Fractions Step 1 Factor each denominator completely, and use the factors to build the LCD. (Remember, the LCD is the smallest number divisible by each of the denominators in the problem.)

Step 2 Rewrite each fraction as an equivalent fraction that has the LCD for its denominator. This is done by multiplying both the numerator and the denominator of the fraction in question by the appropriate whole number.

Step 3 Add or subtract the numerators of the fractions produced in Step 2. This is the numerator of the sum or difference. The denominator of the sum or difference is the LCD.

Step 4 Reduce the fraction produced in Step 3 to lowest terms if it is not already in lowest terms. The idea behind adding or subtracting fractions is really very simple. We can only add or subtract fractions that have the same denominators. If the fractions we are trying to add or subtract do not have the same denominators, we rewrite each of them as an equivalent fraction with the LCD for a denominator. Here are some additional examples of sums and differences of fractions.

EXAMPLE 10 SOLUTION

3 1 Subtract:    5 6 The LCD for 5 and 6 is their product, 30. We begin by rewriting each

3 4

fraction with this common denominator: 36 3 15 1        56 65 5 6 18 5     30 30 13   30

1 5

10. Subtract:   

Answers 17

9.  100

11

10.  20

152

Chapter 2 Fractions and Mixed Numbers

EXAMPLE 11

11. Add. 1 1 1 a.      9 4 6 1 1 1 b.      90 40 60

SOLUTION

1 1 1 Add:      6 8 4 We begin by factoring the denominators completely and building

the LCD from the factors that result: 8222 422

m 8 m 8 m



8 divides the LCD

LCD  2  2  2 m  3 m 24 88 88888 m8 m

623

4 divides the LCD

88 8 88 8 8 6 divides the LCD

We then change to equivalent fractions and add as usual: 14 13 16 4 1 1 3 6 13 1                    64 83 46 6 8 4 24 24 24 24

EXAMPLE 12

3 4

12. Subtract: 2  

SOLUTION

5 Subtract: 3   6 3 The denominators are 1 (because 3  1) and 6. The smallest num-

ber divisible by both 1 and 6 is 6. 36 5 5 3 5 18 5 13 3            16 6 1 6 6 6 6 6

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. When adding two fractions with the same denominators, we always add their __________, but we never add their __________. 2. What does the abbreviation LCD stand for?

5 12

7 18

3. What is the first step when finding the LCD for the fractions  and ? 4. When adding fractions, what is the last step?

Answers 9 9 b. 1 12. 5 11. a. 1 36

360

4

2.5 Problem Set

153

Problem Set 2.5 A Find the following sums and differences, and reduce to lowest terms. (Add or subtract as indicated.) [Examples 1–4] 3 6

1 6

2.   

3 4

1 4

6.   

1 4

2 4

1.   

5.   

3 4

3 10

1 10

9 8

1 8

3.   

5 8

3 8

4.   

7 9

4 9

7.   

2 3

1 3

8.   

2 5

3 5

3 20

4 10

x7 2

4 5

1 20

x5 4

1 2

11.   

4 20

14.     

13.     

1 7

3 5

10.     

9.     

6 7

2 5

1 3

4 3

3 4

12.   

5 3

5 4

15.     

4 4

3 4

16.     

B Complete the following tables. 17.

19.

18.

First Number a

Second Number b

1  3

1

1  2

1  3

1  4

1

1  3

1  4

1  5

1

1  4

1  5

1  6

1

1  5

First Number a

Second Number b

First Number a

Second Number b

1  12

1  2

1  8

1  2

1  12

1  3

1  8

1  4

1  12

1  4

1  8

1  16

1  12

1  6

1  8

1  24

First Number a

Second Number b

1  2

The Sum of a and b ab

The Sum of a and b ab

20.

The Sum of a and b ab

The Sum of a and b ab

154

Chapter 2 Fractions and Mixed Numbers

B Find the LCD for each of the following; then use the methods developed in this section to add or subtract as indicated. [Examples 5–12] 4 9

1 2

1 3

1 3

1 4

1 2

21.   

22.   

25.   1

3 4

26.   2

27.   

1 2

2 3

28.   

1 4

1 5

30.   

1 3

1 5

31.   

1 2

1 5

32.   

5 12

8

34.   

9 16

 12 

35.   

8 30

1 20

36.   

3 10

1 100

38.   

9 100

7 10

39.   

10 36

9 48

40.   

23. 2  

3 4

29.   

3

33.   

37.   

7

24. 3  

1 8

3 4

1 2

1 5

9 40

1 30

12 28

9 20

155

2.5 Problem Set

17 30

11 42

19 42

13 70

43.   

17 84

17 90

47.     

5 21

1 7

41.   

42.   

13 126

46.   

13 180

45.   

3 10

5 12

1 6

49.     

3 14

50.     

2 9

3 5

53. 10  

1 4

25 84

54. 9  

1 8

1 2

23 70

41 90

3 4

1 8

5 6

1 2

1 3

1 4

1 10

4 5

3 20

3 8

1 6

51.       

7 8

3 4

5 8

3 8

2 5

1 4

1 8

1 4

1 5

48.     

1 10

52.       

1 2

55.     

57.       

29 84

44.   

3 4

5 8

56.     

1 2

58.       

There are two ways to work the problems below. You can combine the fractions inside the parentheses first and then multiply, or you can apply the distributive property first, then add.

3 2

3 5

59. 15   



5 4

3 7



2 1

1 4



3 1

61. 4   

1 9

64. Find the sum of 6,  , and 11.

1 4

65. Give the difference of  and  .

1 2



62. 6   

6 11

63. Find the sum of  , 2, and  .

7 8

1 3

60. 15   

9 10

1 100

66. Give the difference of  and  .

156

C

Chapter 2 Fractions and Mixed Numbers

Applying the Concepts

Some of the application problems below involve multiplication or division, while others involve addition or subtraction.

67. Rainfall How much total rainfall did Death Valley get during the months of July and September?

68. Rainfall How much more rainfall did Death Valley get in February than in December?

Death Valley Rainfall

Death Valley Rainfall 1 2

1 4

1 4

1 4

1 4 1 10

0

Jan

Mar

May

inches

measured in inches

1 2

1 4

1 4

1 10

Jul

1 3

3 25

0

Sep

Feb

Nov

1

69. Capacity One carton of milk contains 2 pint while an-

Apr

1 20

1 10

Jun

Aug

2

1 4

1 4

Oct

Dec

3

70. Baking A recipe calls for 3 cup of flour and 4 cup of

other contains 4 pints. How much milk is contained in

sugar. What is the total amount of flour and sugar

both cartons?

called for in the recipe?

71. Budgeting A student earns $2,500 a month while work1

72. Popular Majors Enrollment figures show that the most

of this money for gas ing in college. She sets aside 2 0

popular programs at a local college are liberal art stud-

for food, and 2 for to travel to and from campus, 1 6 5

ies and business programs. The liberal arts studies pro-

savings. What fraction of her income does she plan to

gram accounts for 5 of the student enrollment while

spend on these three items?

of the enrollment. business programs account for 1 0

1

1

1

1

What fraction of student enrollment chooses one of these two areas of study?

73. Exercising According to national studies, childhood

74. Cooking You are making pancakes for breakfast and 3

obesity is on the rise. Doctors recommend a minimum

need 4 of a cup of milk for your batter. You discover

of 30 minutes of exercise three times a week to help

that you only have 2 cup of milk in the refrigerator.

keep us fit. Suppose during a given week you walk for

How much more milk do you need?

1  4

2

3

hour one day, 3 of an hour a second day and 4 of an

hour on a third day. Find the total number of hours walked as a fraction.

1

2.5 Problem Set 1

75. Conference Attendees At a recent mathematics confer1  3

76. Painting Recently you purchased 2 gallon of paint to

were software

paint your dorm room. Once the job was finished you

were representatives from various salespersons, and 1 2

realized that you only used 3 of the gallon. What frac-

book publishing companies. The remainder of the peo-

tional amount of the paint is left in the can?

ence

of the attendees were teachers,

1  4

157

1

1

ple in the conference center were employees of the center. What fraction represents the employees of the conference center?

78. Cutting Wood A 12-foot piece of wood is cut into

77. Subdivision A 6-acre piece of land is subdivided into 3 -acre 5

3

shelves. If each is 4 foot in length, how many shelves

lots. How many lots are there?

are there?

Find the perimeter of each figure.

79.

80. 3 8

3 8

3 8

in.

3 4

in.

81.

82. 3 10 3 5

1 3

in.

in.

1 3

ft

ft

ft 3 5

ft

ft

Arithmetic Sequences Recall that an arithmetic sequence is a sequence in which each term comes from the previous term 3

5

by adding the same number each time. For example, the sequence 1, 2, 2, 2, . . . is an arithmetic sequence that starts with the number 1. Then each term after that is found by adding the next term in the sequence will be

5  2

1

6

1  2

to the previous term. By observing this fact, we know that

 2  2  3.

Find the next number in each arithmetic sequence below. 4 3

5 3

83. 1,  ,  , 2, . . .

5 4

3 2

7 4

84. 1,  ,  ,  , . . .

3 2

5 2

85.  , 2,  , . . .

2 3

4 3

86.  , 1,  , . . .

158

Chapter 2 Fractions and Mixed Numbers

Getting Ready for the Next Section Simplify.

87. 9  6  5

88. 4  6  3

89. Write 2 as a fraction with denominator 8.

90. Write 2 as a fraction with denominator 4.

91. Write 1 as a fraction with denominator 8.

92. Write 5 as a fraction with denominator 4.

Add. 8 4

3 4

94.   

16 8

3 4

97. 1  

93.   

1 8

1 8

95. 2  

1 8

96. 2  

3 4

98. 5  

Divide.

99. 11  4

100. 10  3

101. 208  24

102. 207  26

Maintaining Your Skills Multiply or divide as indicated. 3 4

5 6

1 2

103.   

104. 12  

3 4

1 2

107. 4  

2 3

3 4

7 6

108. 4  

4 5

5 6

6 7

111.         

11 12

2 3

106. 12  

3 4

7 12

110.   

105. 12  

9 10

109.   

10 11

9 10

8 9

7 8

112.         

35 110

80 63

16 27

113.     

20 72

7 10

42 18

20 16

114.     

Mixed-Number Notation

2.6 Objectives A Change mixed numbers to improper

Introduction . . . If you are interested in the stock market, you know that, prior to the year 2000, stock prices were given in eighths. For example, at one point in 1990, one share 5

of Intel Corporation was selling at $73 8, or seventy-three and five-eighths dol-

fractions.

B

Change improper fractions to mixed numbers.

5

lars. The number 738 is called a mixed number. It is the sum of a whole number and a proper fraction. With mixed-number notation, we leave out the addition sign.

Examples now playing at

MathTV.com/books

Notation 3

3

A number such as 5 4 is called a mixed number and is equal to 5  4. It is simply the sum of the whole number 5 and the proper fraction

3  , 4

written without a 

sign. Here are some further examples: 1 1 2  2  , 8 8

5 5 6  6  , 9 9

2 2 11   11   3 3

The notation used in writing mixed numbers (writing the whole number and the proper fraction next to each other) must always be interpreted as addition. It 3

3

is a mistake to read 5 4 as meaning 5 times 4. If we want to indicate multiplication, we must use parentheses or a multiplication symbol. That is: 3 3 5  is not the same as 5  4 4

n 88 88 n

This implies addition

 

n 88 88 n

This implies multiplication

3 3 5  is not the same as 5   4 4

A Changing Mixed Numbers to Improper Fractions To change a mixed number to an improper fraction, we write the mixed number with the  sign showing and then add the two numbers, as we did earlier.

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

3 Change 2 to an improper fraction. 4 3 3 2  2   Write the mixed number as a sum 4 4 3 2     1 4

Show that the denominator of 2 is 1

3 42     41 4

Multiply the numerator and the denominator of 12 by 4 so both fractions will have the same denominator

2 3

1. Change 5 to an improper fraction.

3 8     4 4 11   4

Add the numerators; keep the common denominator

3

The mixed number 24 is equal to the improper fraction lows further illustrates the equivalence of

3 24

and

11 . 4

11  . 4

The diagram that fol-

2.6 Mixed-Number Notation

159

160

Chapter 2 Fractions and Mixed Numbers

+

1

3 4

+

1

=

2

3 4

11 4

EXAMPLE 2

1 6

2. Change 3 to an improper fraction.

SOLUTION

1 Change 2  to an improper fraction. 8

1 1 2  2   8 8

Write as addition

1 2     1 8

Write the whole number 2 as a fraction

1 82     8 81

2 Change  to a fraction with denominator 8 1

1 16     8 8 17   8

Add the numerators

If we look closely at Examples 1 and 2, we can see a shortcut that will let us change a mixed number to an improper fraction without so many steps.

Strategy Changing a Mixed Number to an Improper Fraction (Shortcut) Step 1: Multiply the whole number part of the mixed number by the denominator.

Step 2: Add your answer to the numerator of the fraction. Step 3: Put your new number over the original denominator. 2 3

3. Use the shortcut to change 5 to an improper fraction.

EXAMPLE 3

3 Use the shortcut to change 5 to an improper fraction. 4 SOLUTION 1. First, we multiply 4  5 to get 20.

2. Next, we add 20 to 3 to get 23. 3 4

23 4

3. The improper fraction equal to 5 is . Here is a diagram showing what we have done:

Step 2 Add 20  3  23.

哭3 5 4



Step 1 Multiply 4  5  20.

Mathematically, our shortcut is written like this: (4  5)  3 20  3 23 3 5        4 4 4 4

The result will always have the same denominator as the original mixed number

The shortcut shown in Example 3 works because the whole-number part of a mixed number can always be written with a denominator of 1. Therefore, the LCD for a whole number and fraction will always be the denominator of the fraction. That is why we multiply the whole number by the denominator of the fraction:

Answers 17 3

19 6

17 3

1.  2.  3. 

3 3 5 3 453 23 3 45 5   5               4 4 1 4 4 4 4 41

161

2.6 Mixed-Number Notation

EXAMPLE 4 SOLUTION

5 Change 6  to an improper fraction. 9 Using the first method, we have 5 5 5 6 5 54 5 59 96 6  6                 9 9 1 9 9 9 9 9 91

Using the shortcut method, we have 5 54  5 59 (9  6)  5 6        9 9 9 9

4 9

4. Change 6 to an improper fraction.

CALCULATOR NOTE The sequence of keys to press on a calculator to obtain the numerator in Example 4 looks like this: 9  6  5 

B Changing Improper Fractions to Mixed Numbers To change an improper fraction to a mixed number, we divide the numerator by the denominator. The result is used to write the mixed number.

EXAMPLE 5 SOLUTION

11

11 Change  to a mixed number. 4 Dividing 11 by 4 gives us

5. Change  3 to a mixed number.

Note

2 1  41 8 3 We see that 4 goes into 11 two times with 3 for a remainder. We write this as

This division process shows us how many ones are in 141 and, when the ones are taken out, how many fourths are left.

11 3 3   2    2 4 4 4 3 11 The improper fraction  is equivalent to the mixed number 2  . 4 4 An easy way to visualize the results in Example 5 is to imagine having 11 quarters. Your 11 quarters are equivalent to worth 2 dollars plus 3 quarters, or

3 24

11  4

dollars. In dollars, your quarters are

dollars.

=

EXAMPLE 6 SOLUTION

10 : 3

+

Change each improper fraction to a mixed number. 14 6.  5

10 Change  to a mixed number. 3 3 0  31 9

so

1 1 10   3    3 3 3 3

1

EXAMPLE 7 SOLUTION

208 : 24

208 Change  to a mixed number. 24 8

16

so

208 16 2 2   8    8    8 24 24 3 3 m

0 8  242 192

207 26

7. 

Reduce to lowest terms

Answers 58 9

2 3

4 5

25 26

4.  5. 3 6. 2 7. 7

162

Chapter 2 Fractions and Mixed Numbers

Long Division, Remainders, and Mixed Numbers Mixed numbers give us another way of writing the answers to long division problems that contain remainders. Here is how we divided 1,690 by 67 in Chapter 1: 25 R 15 ,6 9  0 671 6 6 1 34 6  g 350 335  15 The answer is 25 with a remainder of 15. Using mixed numbers, we can now 15

. That is, write the answer as 256 7 1,690 15   25 67 67 15

The quotient of 1,690 and 67 is 256 . 7

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. What is a mixed number? 3 2. The expression 5 is equivalent to what addition problem? 4 11 3. The improper fraction  is equivalent to what mixed number? 4 13 3 4. Why is  an improper fraction, but  is not an improper fraction? 5 5

163

2.6 Problem Set

Problem Set 2.6 A Change each mixed number to an improper fraction. [Examples 1–4] 2 3

1. 4 

2 3

7. 15 

5 8

2. 3 

3 4

8. 17 

1 4

4. 7 

20 21

10. 5 

3. 5 

9. 4 

1 2

18 19

5 8

5. 1 

31 33

11. 12 

6 7

6. 1 

29 31

12. 14 

B Change each improper fraction to a mixed number. [Examples 5–7] 9 8

14. 

13 4

20. 

13. 

19. 

10 9

15. 

19 4

16. 

41 15

21. 

23 5

17. 

109 27

22. 

29 6

18. 

319 23

23. 

7 2

428 15

24. 

769 27

164

Chapter 2 Fractions and Mixed Numbers

Getting Ready for the Next Section Change to improper fractions. 3 4

1 5

25. 2

5 8

26. 3

27. 4

3 5

4 5

28. 1

9 10

29. 2

30. 5

Find the following products. (Multiply.) 3 8

3 5

31.   

11 4

16 5

3 4

1 2

32.   

7 10

33.  

2 9 3 16

34.  

8 5

38.   2

 

5

 21 

Find the quotients. (Divide.) 4 5

7 8

35.   

36.   

14 5

37.   

Maintaining Your Skills Perform the indicated operations. 2 3

3 4

5 8

39.     

3 4

7 6

40. 4    7

2 3

1 6

1 2

42.     12

6 7

44. 15    16

41.     6

43. 12    7

5 8

59 10

Multiplication and Division with Mixed Numbers

Objectives A Multiply mixed numbers. B Divide mixed numbers. C Solve applications involving

Introduction . . . The figure here shows one of the nutrition labels we worked with in Chapter 1. It is from a can of Italian tomatoes. Notice toward the top of the label, the number of servings in 1

1

the can is 32. The number 32 is called a mixed number. If we want to know how many calories are in the whole can of toma1 32

2.7

CANNED ITALIAN TOMATOES

Nutrition Facts

multiplying and dividing mixed numbers.

Serving Size 1/2 cup (121g) Servings Per Container: about 3 1/2 Amount Per Serving Calories from fat 0

Calories 25

% Daily Value* 0%

Total Fat 0g Saturated Fat 0g Cholesterol 0mg

0%

Examples now playing at

(the number of calories per serving). Multi-

0%

MathTV.com/books

plication with mixed numbers is one of the

Sodium 300mg Potassium 145mg

12% 4%

toes, we must be able to multiply

by 25

topics we will cover in this section. The procedures for multiplying and divid-

Total Carbohydrate 4g Dietary Fiber 1g

2% 4%

Sugars 4g

ing mixed numbers are the same as those we

Protein 1g

used in Sections 2.3 and 2.4 to multiply and

Vitamin A 20%

divide fractions. The only additional work in-

Calcium 4%

volved is in changing the mixed numbers to

*Percent Daily Values are based on a 2,000 calorie diet. Your daily values may be higher or lower depending on your calorie needs.

improper fractions before we actually multi-

• •

Vitamin C 15% Iron 15%

ply or divide.

A Multiplying Mixed Numbers PRACTICE PROBLEMS

EXAMPLE 1 Multiply: 2 3  3 1 4 5 SOLUTION We begin by changing each mixed number to an improper fraction: 11 3 2   4 4

and

3 4

1 3

1. Multiply: 2  4

1 16 3   5 5

Using the resulting improper fractions, we multiply as usual. (That is, we multiply numerators and multiply denominators.) 11 16 11  16      4 5 45 11   44    45 44   5

or

4 8 5

EXAMPLE 2 SOLUTION

5 Multiply: 3  4  8 Writing each number as an improper fraction, we have 3 3  1

and

5 37 4   8 8

The complete problem looks like this: 3 37 5 3  4     8 1 8 111   8 7  13  8

Change to improper fractions

5 8

2. Multiply: 2  3

Note

As you can see, once you have changed each mixed number to an improper fraction, you multiply the resulting fractions the same way you did in Section 2.3.

Multiply numerators and multiply denominators Write the answer as a mixed number

Answers 11 12

1 4

1. 11 2. 7

2.7 Multiplication and Division with Mixed Numbers

165

166

Chapter 2 Fractions and Mixed Numbers

B Dividing Mixed Numbers Dividing mixed numbers also requires that we change all mixed numbers to improper fractions before we actually do the division.

3 5

2 5

3. Divide: 1  3

EXAMPLE 3 SOLUTION

3 4 Divide: 1   2  5 5 We begin by rewriting each mixed number as an improper fraction: 3 8 1   5 5

and

4 14 2   5 5

We then divide using the same method we used in Section 2.4. Remember? We multiply by the reciprocal of the divisor. Here is the complete problem: 4 8 14 3 1  2     5 5 5 5 5 8     5 14

To divide by 5, multiply by 14

85   5  14

Multiply numerators and multiply denominators

4 2 5    5 27

Divide out factors common to the numerator and denominator

4   7

5 8

4. Divide: 4  2

Change to improper fractions 14

5

Answer in lowest terms

EXAMPLE 4 SOLUTION

9 Divide: 5   2 10 We change to improper fractions and proceed as usual: 9 59 2 5  2     10 10 1

Write each number as an improper fraction

59 1     10 2

Write division as multiplication by the reciprocal

59   20

Multiply numerators and multiply denominators

19  2 20

Change to a mixed number

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. What is the first step when multiplying or dividing mixed numbers? 4 2. What is the reciprocal of 2 ? 5 9 9 3. Dividing 5 by 2 is equivalent to multiplying 5 by what number? 10 10 5 4. Find 4  of 3. 8 Answers 8 17

5 16

3.  4. 2

2.7 Problem Set

Problem Set 2.7 A Write your answers as proper fractions or mixed numbers, not as improper fractions. Find the following products. (Multiply.) [Examples 1, 2] 2 5

1 3

1 2

1. 3   1 

1 10

3 10

5. 2   3 

3. 5   2 

1 8

2 3

4. 1   1 

7 10

7. 1   4 

1 4

2 3

8. 3   2 

3 4

1 10

6. 4   3 

7 8

1 4

9. 2  4 

1 2

2. 2   6 

3 5

10. 10  1 

1 3

1 5

1 2

13. 2   3   1 

1 6

1 8

3 4

4 5

1 2

1 6

2 3

1 3

11.   5 

14. 3   5   1 

5 6

9 10

12.   4 

4 5

5 6

7 8

15.   7  1 

16.   6  1 

B Find the following quotients. (Divide.) [Examples 3, 4] 1 5

4 5

1 2

17. 3   4 

1 2

1 6

21. 10  2 

25.

3

22. 12  3 

7 8

1

 4  2 2   3

1 2



2 5

1 4

5 6

18. 1   2 



1 4



3 5





1 4



1 3

20. 8   4 

3 5

24. 12   3

6 7

23. 8   2

26.   1   4

29. 2   3   4

2 3

3 4

19. 6   3 



1 4





27. 8  1   2

30. 4   2   5

1 2

1 5

31. Find the product of 2  and 3.

3 4

2 3

32. Find the product of  and 3  .

1 4

33. What is the quotient of 2  and 3  ?

1 4



28. 8  1   2

1 5

2 5

34. What is the quotient of 1  and 2  ?

167

168

C

Chapter 2 Fractions and Mixed Numbers

Applying the Concepts 3

35. Cooking A certain recipe calls for 24 cups of sugar. If

1

36. Cooking A recipe calls for 34 cups of flour. If Diane is

the recipe is to be doubled, how much sugar should be

using only half the recipe, how much flour should she

used?

use?

3

7

37. Number Problem Find 4 of 19. (Remember that of means

5

4

38. Number Problem Find 6 of 2 1 . 5

multiply.)

9

39. Cost of Gasoline If a gallon of gas costs 335 1 ¢, how 0

9

40. Cost of Gasoline If a gallon of gas costs 3531 ¢, how 0 much does

much do 8 gallons cost?

3

41. Distance Traveled If a car can travel 32 4 miles on a gallon of gas, how far will it travel on 5 gallons of gas?

1  2

gallon cost?

1

42. Sewing If it takes 12 yards of material to make a pillow cover, how much material will it take to make 3 pillow covers?

43. Buying Stocks Assume that you have $1000 to invest in

3

44. Subdividing Land A local developer owns 1454 acres of 1 22

acre home site

the stock market. Because you own an iPod™ and an

land that he hopes to subdivide into

iPhone™, you decide to buy Apple stock. It is currently

lots to sell. How many home sites can be developed

7

selling at a cost of $1508 per share. At this price how

from this tract of land?

many shares can you buy?

45. Selling Stocks You inherit 100 shares of Cisco stock that 1

46. Gas Mileage You won a new car and are anxious to see 1

has a current value of $256 per share. How much will

what kind of gas mileage you get. You travel 4275

you receive when you sell the stock?

miles before needing to fill your tank. You purchase 134

3

gallons of gas. How many miles were you able to travel on a single gallon of gas?

1

47. Area Find the area of a bedroom that measures 112 ft by

7 158

ft.

48. Building Shelves You are building a small bookcase. You 7

need three shelves, each with a length of 48 ft. You bought a piece of wood that is 15 ft long. Will this board be long enough?

2.7 Problem Set 49. The Google Earth image shows some fields in the mid-

169

50. The Google Earth map shows Crater Lake National

western part of the United States. The rectangle outlines

Park in Oregon. If Crater Lake is roughly the shape of a

a corn field, and gives the dimensions in miles. Find the

circle with a radius of 22 miles, how long is the shore-

1

line? Use

area of the corn field written as a mixed number.

22  7

for π.

21/2 miles

11/4 miles 23/4 miles

Nutrition The figure below shows nutrition labels for two different cans of Italian tomatoes. CANNED TOMATOES 2

CANNED TOMATOES 1

Nutrition Facts

Nutrition Facts

Serving Size 1/2 cup (121g) Servings Per Container: about 3 1/2

Serving Size 1/2 cup (121g) Servings Per Container: about 3 1/2

Amount Per Serving

Amount Per Serving Calories from fat 0

Calories 45

% Daily Value* 0%

Total Fat 0g Saturated Fat 0g Cholesterol 0mg

0% 0%

Sodium 560mg

23%

Total Carbohydrate 11g Dietary Fiber 2g

4% 8%

Sugars 9g

Calcium 2%

Saturated Fat 0g Cholesterol 0mg

0%

Sodium 300mg Potassium 145mg

12% 4%

0%

Total Carbohydrate 4g Dietary Fiber 1g

2% 4%

Protein 1g

• •

Vitamin C 25% Iron 2%

*Percent Daily Values are based on a 2,000 calorie diet.

Vitamin A 20% Calcium 4%

• •

Vitamin C 15% Iron 15%

*Percent Daily Values are based on a 2,000 calorie diet. Your daily values may be higher or lower depending on your calorie needs.

51. Compare the total number of calories in the two cans of tomatoes.

53. Compare the total amount of sodium in the two cans of tomatoes.

% Daily Value* 0%

Total Fat 0g

Sugars 4g

Protein 1g Vitamin A 10%

Calories from fat 0

Calories 25

52. Compare the total amount of sugar in the two cans of tomatoes.

54. Compare the total amount of protein in the two cans of tomatoes.

170

Chapter 2 Fractions and Mixed Numbers

Getting Ready for the Next Section 55. Write as equivalent fractions with denominator 15. 2 3

1 5

a. 

3 5

b. 

1 3

c. 

d. 

57. Write as equivalent fractions with denominator 20. 1 a.  4

3 b.  5

9 c.  10

1 d.  10

56. Write as equivalent fractions with denominator 12. 3 4

1 3

a. 

b. 

5 6

1 4

c. 

d. 

58. Write as equivalent fractions with denominator 24. 3 4

7 8

a. 

b. 

5 8

3 8

c. 

d. 

Maintaining Your Skills Add or subtract the following fractions, as indicated. 2 3

1 5

3 4

5 6

59.   

60.   

9 10

64.   

7 10

3 10

63.   

3 5

1 4

8 9

2 3

3 21

1 14

3 5

9 10

62.     

61.   

65.   

1 3

5 12

66.   

Extending the Concepts To find the square of a mixed number, we first change the mixed number to an improper fraction, and then we square the result. For example:

22  2 1

2

5

2

25   4

1 If we are asked to write our answer as a mixed number, we write it as 6. 4 Find each of the following squares, and write your answers as mixed numbers. 1

 2

67. 1 

2

1

 2

68. 3 

2

3

 4

69. 1 

2

3

 4

70. 2 

2

Addition and Subtraction with Mixed Numbers

Objectives A Perform addition and subtraction

Introduction . . . In March 1995, rumors that Michael Jordan would return to basketball sent stock prices for the companies whose products he endorsed higher. The price of one share of General Mills, the maker of Wheaties, which Michael Jordan endorses, 1

2.8

3

went from $60 2 to $63 8. To find the increase in the price of this stock, we must be able to subtract mixed numbers.

with mixed numbers.

B

Perform subtraction involving borrowing with mixed numbers.

C

Solve application problems involving addition and subtraction with mixed numbers.

The notation we use for mixed numbers is especially useful for addition and subtraction. When adding and subtracting mixed numbers, we will assume you recall how to go about finding a least common denominator (LCD). (If you don’t remember, then review Section 2.5.)

Examples now playing at

MathTV.com/books

A Combining Mixed Numbers

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

2 1 Add: 3  4 3 5 Method 1: We begin by writing each mixed number showing the 

2 3

1 4

1. Add: 3  2

sign. We then apply the commutative and associative properties to rearrange the order and grouping: 2 1 2 1 3  4  3    4   3 5 3 5

Expand each number to show the  sign

2 1 34    3 5

Commutative property

1 2  (3  4)     3 5





52 31 7    53 35



3 10 7    15 15



13 7  15 13  7 15





Associative property Add 3  4  7; then multiply to get the LCD Write each fraction with the LCD Add the numerators Write the answer in mixed-number notation

Method 2: As you can see, we obtain our result by adding the whole-number parts (3  4  7) and the fraction parts

(32  51  1153 ) of each mixed number. Know-

ing this, we can save ourselves some writing by doing the same problem in columns: 25 10 2 3  3  3 3 35 15 13 3 1  4  4  4 5 53 15

Add whole numbers Then add fractions

Note

You should try both methods given in Example 1 on Practice

m888888

Problem 1.

13 7 15

Write each fraction with LCD 15 The second method shown above requires less writing and lends itself to mixed-number notation. We will use this method for the rest of this section.

2.8 Addition and Subtraction with Mixed Numbers

Answer 1 1. 51 12

171

172

Chapter 2 Fractions and Mixed Numbers

3 4

EXAMPLE 2

4 5

2. Add: 5  6

SOLUTION

3 5 Add: 5   9  4 6 The LCD for 4 and 6 is 12. Writing the mixed numbers in a column

and then adding looks like this: 3 33 9 5  5  5 4 43 12 5 52 10  9  9  9 6 62 12 19 14  12

Note

Once you see how to change from a whole number and an improper fraction to a whole number and a proper fraction, you will be able to do this step without showing any work.

3 4

The fraction part of the answer is an improper fraction. We rewrite it as a whole number and a proper fraction: 19 19 14   14   12 12

EXAMPLE 3

7 8

3. Add: 6  2

SOLUTION

Write the mixed number with a  sign

7  14  1  12

 as a mixed number Write  12

7  15  12

Add 14 and 1

19

2 8 Add: 5   6  3 9

23 6 2 5  5  5 3 33 9 8 8  6  6 9 9

8  6 9 5 14 11   12  9 9

14 5 The last step involves writing  as 1  and then adding 11 and 1 to get 12. 9 9

1 3

1 4

11 12

4. Add: 2  1  3

EXAMPLE 4 SOLUTION

1 3 9 Add: 3   2   1  4 5 10 The LCD is 20. We rewrite each fraction as an equivalent fraction

with denominator 20 and add: 15 1 3  3 4 45

5  3 20

34 3 2  2 5 54

12  2 20

m

9 92 18  1  1  1 10 10  2 20 35 15 3 6   7  7 20 20 4

Reduce to lowest terms

m 35 15   1 20 20

Change to a mixed number

Answers 11 20

5 8

1 2

2. 12 3. 9 4. 7

We should note here that we could have worked each of the first four examples in this section by first changing each mixed number to an improper fraction and

173

2.8 Addition and Subtraction with Mixed Numbers then adding as we did in Section 2.5. To illustrate, if we were to work Example 4 this way, it would look like this: 3 9 13 13 19 1 3  2  1       4 5 10 4 5 10

Change to improper fractions

13  5 13  4 19  2       45 54 10  2

LCD is 20

52 38 65       20 20 20

Equivalent fractions

155   20

Add numerators

15 3  7  7 20 4

Change to a mixed number, and reduce

As you can see, the result is the same as the result we obtained in Example 4. There are advantages to both methods. The method just shown works well when the whole-number parts of the mixed numbers are small. The vertical method shown in Examples 1–4 works well when the whole-number parts of the mixed numbers are large. Subtraction with mixed numbers is very similar to addition with mixed numbers.

EXAMPLE 5

3 9 Subtract: 3   1  10 10

7 8

5 8

5. Subtract: 4  1

SOLUTION Because the denominators are the same, we simply subtract the whole numbers and subtract the fractions: 9 3 10 3  1 10 6 3 2  2 10 5 m

Reduce to lowest terms An easy way to visualize the results in Example 5 is to imagine 3 dollar bills and 9 dimes in your pocket. If you spend 1 dollar and 3 dimes, you will have 2 dollars and 6 dimes left.

+

EXAMPLE 6

7 3 Subtract: 12   8  10 5

7 10

SOLUTION The common denominator is 10. We must rewrite 53 as an equivalent fraction with denominator 10: 7 7 12   12  10 10

7  12  10

3 32 6  8   8   8 5 52 10 1 4 10

2 5

6. Subtract: 12  7

Answers 1 4

3 10

5. 3 6. 5

174

Chapter 2 Fractions and Mixed Numbers

B Borrowing with Mixed Numbers 4 7

7. Subtract: 10  5

EXAMPLE 7 SOLUTION

Note

Convince yourself that 10 is the same as 9 77. The reason we choose to write the 1 we borrowed as 77 is that the fraction we eventually subtracted from 77 was 72. Both fractions must have the same denominator, 7, so that we can subtract. 1 3

2 3

8. Subtract: 6  2

2 Subtract: 10  5  7 In order to have a fraction from which to subtract 7 . 7

2  , 7

we borrow 1

The process looks like this: from 10 and rewrite the 1 we borrow as 7 7 7 10  9  m888 We rewrite 10 as 9  1, which is 9    9  7 7 7 2 2  5   5 7 7

Then we can subtract as usual

5 4 7

EXAMPLE 8 SOLUTION

1 3 Subtract: 8   3  4 4 3 1 Because 4 is larger than 4, we again need to borrow 1 from the

whole number. The 1 that we borrow from the 8 is rewritten as

4  , 4

because 4 is

the denominator of both fractions: 1 8  4

5 7 4

m8888888

4 4

Borrow 1 in the form ;

4 1 5 then 4  4  4

3 3  3   3 4 4 2 1 4  4 4 2 3 4

5 6

9. Subtract: 6  2

Reduce to lowest terms

EXAMPLE 9 SOLUTION

5 3 Subtract: 4   1  4 6 This is about as complicated as it gets with subtraction of mixed

numbers. We begin by rewriting each fraction with the common denominator 12: 3 4  4

33 4  43

9 4 12

52 10 5  1   1   1 6 62 12 Because subtract:

10  12

is larger than 9 4  12

9  , 12

we must borrow 1 from 4 in the form

12  12

before we

9 9 12 12 21 3  m888 4  3  1  3  , so 4   3     12 12 12 12 12





12

10 10  1   1 12 12

 12

9 12



 3    

21 12

11 2 12

 3  

21 12

 3 

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 3

9

1. Is it necessary to “borrow” when subtracting 110 from 3 10? 2.

Answers 3 2 7. 4 8. 3 7 3

11 9. 3 12

2 To subtract 17

from 10, it is necessary to rewrite 10 as what mixed number? 20

3

3

 from 15 , it is necessary to rewrite 15  as what 3. To subtract 11 30 30 30 mixed number? 19

4. Rewrite 14 12 so that the fraction part is a proper fraction instead of an improper fraction.

2.8 Problem Set

Problem Set 2.8 A Add and subtract the following mixed numbers as indicated. [Examples 1–6] 1 5

3 5

2. 8   1 

2 9

8 9

4 9

6. 12   7 

5 8

1 4

1. 2   3 

5 12

5. 6   3 

3 10

5 9

1 12

5 12

15. 6   4 

7 8

1 6

19. 5  6 

18. 11   9 

21.

13 10 16

22.

5  8 16

25.

5 1 8 3  1 4

29.

4 5 10 1  3 3

7 17 12

23.

6 7 7

27.

7 8

5  3 6

5 8

1 2

4 5

1 3

5 6

5 6

1 3

1 4

16. 5   3 

2 3

1 3

20. 8  9 

1 6 2

24.

2 4 3

31.

1 10 20 4  11 5

11 9 12 1  4 6

28.

3  5 5

3  2 14

30. 12

5 6

5  2 14

5  9  12

26.

3 4

12. 1   2 

3 4

5 6

1 4

1 3

14. 7   3 

5 12

3 7

8. 9   5 

11. 11   2 

13. 7   3 

3 4

5 6

3 5

10. 7   6 

17. 10   15 

1 6

2 7

4. 5   3 

7. 9   2 

9 10

9. 3   2 

1 3

1 10

3. 4   8 

4 9 9 1  1 6

32.

7 18 8 1  19 12

175

176

Chapter 2 Fractions and Mixed Numbers

A Find the following sums. (Add.) [Examples 1–4] 1 4

3 4

33. 1  2  5

3 4

1 4

37.   8  5

41.

2 8 3

3 5

2 5

34. 6  5  8

5 8

1 8

38.   1  7

42.

3 7 5

1 9 8

2 8 3

1  6 4

1  1 5

1 10

3 10

7 10

35. 7  8  2 

1 2

1 3

1 6

39. 3  8  5

43.

1 6 7

2 7

1 7

5 7

1 5

1 3

1 15

36. 5  8  3

40. 4  7  8

44.

5 1 6 3 2 4

3 9 14 1  12 2

1  5 2

B The following problems all involve the concept of borrowing. Subtract in each case. [Examples 7–9] 3 4

3 10

1 3

45. 8  1

46. 5  3

1 4

3 4

50. 12  5 

1 4

1 3

54. 6  1

3 10

49. 8  2

1 5

53. 4  2

7 10

2 3

48. 24  10

1 3

2 3

52. 7  6

1 6

2 3

3 4

56. 12  8

51. 9   8

3 4

4 5

58. 18  9 

5 12

3 4

59. 10  4 

1 6

5 8

62. 21  20 

2 5

5 6

63. 15  11

3 10

3 10

5 6

5 6

55. 9  5

57. 16  10

61. 13   12

5 12

47. 15  5

4 5

4 5

4 7

7 8

2 3

60. 9  7

3 15

2 3

64. 19  10

177

2.8 Problem Set

C

Applying the Concepts

Stock Prices As we mentioned in the introduction to this section,

Stock Prices for Companies with Michael Jordan Endorsements

in March 1995, rumors that Michael Jordan would return to basketball sent stock prices for the companies whose products he endorses higher. The table at the right gives some of the

Company

Stock Price (Dollars) 3/8/95 3/13/95

Product Endorsed

details of those increases. Use the table to work Problems 65–70. Nike

7 74 8 1 32 4 1 60 2 7 32 8

Air Jordans

Quaker Oats

Gatorade

General Mills

Wheaties

McDonald’s

65. Find the difference in the price of Nike stock between

3 77 8 5 32 8 3 63 8 3 34 8

66. Find the difference in price of General Mills stock be-

March 13 and March 8.

tween March 13 and March 8.

67. If you owned 100 shares of Nike stock, how much more

68. If you owned 1,000 shares of General Mills stock on

are the 100 shares worth on March 13 than on March 8?

March 8, how much more would they be worth on March 13?

69. If you owned 200 shares of McDonald’s stock on March

70. If you owned 100 shares of McDonald’s stock on March

8, how much more would they be worth on March 13?

8, how much more would they be worth on March 13?

71. Area and Perimeter The diagrams below show the dimensions of playing fields for the National Football League (NFL), the Canadian Football League, and Arena Football.

Football Fields 110 yd 100 yd

65 yd

53 13 yd

50yd 28 13 yd

NFL

Canadian

a. Find the perimeter of each football field.

Arena

b. Find the area of each football field.

72. Triple Crown The three races that constitute the Triple Crown in horse racing are shown in the table. The information comes from the ESPN website.

Race

a. Write the distances in order from smallest to largest.

Kentucky Derby Preakness Stakes

b. How much longer is the Belmont Stakes race than the Preakness Stakes? Belmont Stakes

1

Distance (miles) 1 1 4 3 1 16 1 1 2

73. Length of Jeans A pair of jeans is 32 2 inches long. How

74. Manufacturing A clothing manufacturer has two rolls of

long are the jeans after they have been washed if they

cloth. One roll is 35 2 yards, and the other is 62 8 yards.

shrink

1 13

inches?

1

5

What is the total number of yards in the two rolls?

178

Chapter 2 Fractions and Mixed Numbers

Getting Ready for the Next Section Multiply or divide as indicated. 11 8

29 8

75.   

3 4

5 6

77.   

7 6

1 2

2 3

81. 2  1

82. 3  4

76.   

12 7

1 3

2 3

78. 10  8

Combine. 3 4

5 8

79.   

3 8

80.   

1 4

2 3

1 3

Maintaining Your Skills Use the rule for order of operations to combine the following.

83. 3  2  7

84. 8  3  2

85. 4  5  3  2

86. 9  7  6  5

87. 3  23  5  42

88. 6  52  2  33

89. 3[2  5(6)]

90. 4[2(3)  3(5)]

91. (7  3)(8  2)

92. (9  5)(9  5)

Extending the Concepts 1 5

7 10

93. Find the difference between 6 and 2.

1 8

3 5

95. Find the sum of 3 and 2.

1 3

5 6

94. Give the difference between 5 and 1.

5 6

4 9

96. Find the sum of 1 and 3.

97. Improving Your Quantitative Literacy A column on horse racing in the Daily News in 1

Los Angeles reported that the horse Action This Day ran 3 furlongs in 35 5 seconds and another horse, Halfbridled, went two-fifths of a second faster. How many sec-

Santa Anita Race Track

onds did it take Halfbridled to run 3 furlongs?

ACTION THIS DAY HALFBRIDLED

35.2 SECONDS _____ SECONDS

Combinations of Operations and Complex Fractions

2.9 Objectives A Simplify expressions involving

Introduction . . . Now that we have developed skills with both fractions and mixed numbers, we can simplify expressions that contain both types of numbers.

A Simplifying Expressions Involving Fractions

fractions and mixed numbers.

B C

Simplify complex fractions. Solve application problems involving mixed numbers.

and Mixed Numbers Examples now playing at

EXAMPLE 1 SOLUTION 1

1 2 Simplify the expression: 5  2 3 2 3 The rule for order of operations indicates that we should multiply

  

2

22 times 33 and then add 5 to the result:

  

  

Change the mixed numbers to improper fractions

55  5   6

Multiply the improper fractions

30 55     6 6

Write 5 as 360 so both numbers have the same denominator

85   6 1  14 6

EXAMPLE 2

1 3 4  1 2 2 4

  

Add fractions by adding their numerators Write the answer as a mixed number

5 3 3 1 Simplify:    2   1  4 8 4 8 We begin by combining the numbers inside the parentheses:



3 5 32 5        4 8 42 8

PRACTICE PROBLEMS 1. Simplify the expression:

1 2 5 11 5  2 3  5    2 3 2 3

SOLUTION

MathTV.com/books





3 2  8

and

3 2 8



2. Simplify: 2

1

5

1

3  626  13

3 2 8

1 12 2  1   1   1 4 42 8

6 5     8 8 11   8

5 3 8

Now that we have combined the expressions inside the parentheses, we can complete the problem by multiplying the results: 3

5

3

1

11

5

4  828  14  838 11 29     8 8

Change 38 to an improper fraction

319   64

Multiply fractions

63  4 64

Write the answer as a mixed number

5

Answers 1 8

17 36

1. 8 2. 3

2.9 Combinations of Operations and Complex Fractions

179

180

Chapter 2 Fractions and Mixed Numbers

EXAMPLE 3

3. Simplify: 3 1 1 1    1  4 7 3 2 2





2

3 1 2 1 2 Simplify:    3  4 5 2 3 3 We begin by combining the expressions inside the parentheses:

SOLUTION



3 1 2 1    3  4 5 2 3 3





2



3 1    (8)2 5 2

The sum inside the parentheses is 8

3 1    (64) 5 2

The square of 8 is 64

3    32 5

1  of 64 is 32 2

3  32 5

The result is a mixed number

B Complex Fractions Definition A complex fraction is a fraction in which the numerator and/or the denominator are themselves fractions or combinations of fractions.

Each of the following is a complex fraction: 3  4 , 5  6

1 3   2 , 3 2   4

1 2    2 3  3 1    4 6

3  4 Simplify:  5  6 This is actually the same as the problem

EXAMPLE 4

4. Simplify: 2  3  5  9

SOLUTION tween

3  4

and

5  6

3  4

5

 6, because the bar be-

indicates division. Therefore, it must be true that 3  3 5 4      5 4 6  6 3 6     4 5 18   20 9   10

As you can see, we continue to use properties we have developed previously when we encounter new situations. In Example 4 we use the fact that division by a number and multiplication by its reciprocal produce the same result. We are taking a new problem, simplifying a complex fraction, and thinking of it in terms of a problem we have done previously, division by a fraction.

Answers 3 7

1 5

3. 12 4. 1

181

2.9 Combinations of Operations and Complex Fractions

EXAMPLE 5 SOLUTION

1 2    2 3 Simplify:  3 1    4 6

5.

Let’s decide to call the numerator of this complex fraction the top of

the fraction and its denominator the bottom of the complex fraction. It will be less confusing if we name them this way. The LCD for all the denominators on the top and bottom is 12, so we can multiply the top and bottom of this complex fraction

1 3    2 4 Simplify:  2 1    3 4

Note

We are going to simplify this complex fraction by two different methods. This is the first method.

by 12 and be sure all the denominators will divide it exactly. This will leave us with only whole numbers on the top and bottom: 1 2 1 2    12    2 3 2 3    3 1 3 1    12    4 6 4 6 1 2 12    12   2 3   3 1 12    12   4 6

 

 

Multiply the top and bottom by the LCD

Distributive property

68   92

Multiply each fraction by 12

14   7

Add on top and subtract on bottom

2

Reduce to lowest terms

The problem can be worked in another way also. We can simplify the top and bottom of the complex fraction separately. Simplifying the top, we have 13 22 1 2 3 4 7              23 32 2 3 6 6 6 Simplifying the bottom, we have 33 12 3 1 9 2 7                 4  3 6 2 4 6 12 12 12 We now write the original complex fraction again using the simplified expressions for the top and bottom. Then we proceed as we did in Example 4.

Note

The fraction bar that separates the numerator of the complex fraction from its denominator works like parentheses. If we were to rewrite this problem without it, we would write it like this: 1 2 3 1 2  3  4  6 That is why we simplify the top and bottom of the complex fraction separately and then divide.

1 7 2     3 2 6    7 3 1     12 4 6 7 7     6 12

 The divisor is  12

7 12     6 7

 by its reciprocal and multiply Replace  12

2 7 6    6 7

Divide out common factors

7

7

2

STUDY SKILLS Review with the Exam in Mind Each day you should review material that will be covered on the next exam. Your review should consist of working problems. Preferably, the problems you work should be problems from your list of difficult problems.

Answer 5. 3

182

6.

Chapter 2 Fractions and Mixed Numbers

2 4   3  Simplify: 1 3   4

EXAMPLE 6 SOLUTION

1 3   2 Simplify:  3 2   4

The simplest approach here is to multiply both the top and bottom

by the LCD for all fractions, which is 4: 1 1 3   4 3   2 2    3 3 2   4 2   4 4

 

 

Multiply the top and bottom by 4

1 4  3  4   2   3 4  2  4   4 12  2   83

Distributive property

Multiply each number by 4

14   5

Add on top and subtract on bottom

4  2 5

7.

1 12 3 Simplify:  2 6  3

EXAMPLE 7 SOLUTION

1 10 3 Simplify:  2 8  3

The simplest way to simplify this complex fraction is to think of it as

a division problem. 1 10 1 2 3   10  8 2 3 3 8  3 31 26     3 3

Write with a  symbol Change to improper fractions

31 3     3 26

Write in terms of multiplication

31   3   3   26

Divide out the common factor 3

31 5    1 26 26

Answer as a mixed number

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. What is a complex fraction? 5  6 2. Rewrite  1 as a multiplication problem.  3 3. True or false? The rules for order of operations tell us to work inside parentheses first. 4. True or false? We find the LCD when we add or subtract fractions, but not when we multiply them.

Answers 23 33

17 20

6. 1 7. 1

183

2.9 Problem Set

Problem Set 2.9 A Use the rule for order of operations to simplify each of the following. [Examples 1–3] 1

2

3

 2  3 

2 3

1

3 4

 2

1

2 5

 3

3

1 10



5 6

1



9.      



5 6



13. 1   1  

3 8

1 1 2 3



5 3

5 8

2

1

1

 5



3

1

2

1 3

11. 2   3  



1 4

15.    2   



1 10

1 4





2 3

1 8 3 5



7 5



18. 8      

2

3

 2  5



2 3

2 3

1 3

1

2

1 8





1 3

1 2

8. 4 5   6 3 



1 2

2



3 4

3 5

1 4

1 3





12. 3   3  



 3

5

 4  6

7. 2 1  5 6 

9

 5

5

4. 10  2  

10.      

14. 2   2  

17. 2      

4

 5  7 

3. 8   1

6.  2    3 

3 4

 2

1

 2

5

 11  6 

2. 7  1 2

5.  1   1

5

6

1

 5  2 

1. 3  1 2 

2



1 2

1 2



16.    2   

1 4



19. 2     3   

1

5

3 10

3

1

  10

1 2



20. 5     2   

184

Chapter 2 Fractions and Mixed Numbers

B Simplify each complex fraction as much as possible. [Examples 4–7] 2  3 21.  3  4

5  6 22.  3  12

2  3 23.  4  3

7  9 24.  5  9

11  20 25.  5  10

9  16 26.  3  4

1 1    2 3 27.  1 1    2 3

1 1    4 5 28.  1 1    4 5

5 1    8 4 29.  1 1    8 2

3 1    4 3 30.  2 1    3 6

9 1    20 10 31.  1 9    10 20

1 2    2 3 32.  3 5    4 6

2 1   3 33.  2 1   3

3 5   4 34.  3 2   4

5 2   6 35.  1 5   3

11 9   5 36.  13 3   10

5 3   6 37.  5 1   3

9 10   10 38.  4 5   5

1 3    3 4 39.  1 2   6

5 3   2 40.  5 1    6 4

5  6 41.  2 3   3

3 9   2 42.  7  4

2.9 Problem Set

B Simplify each of the following complex fractions. [Examples 5–7] 1 1 2   2 2 43.  3 2 3   5 5

3 5 5   8 8 44.  1 3 4  1 4 4

2 2  1 3 45.  5 3  1 6

3 5  8 5 46.  3 2   4 10

1 1 3  2 4 2 47.  3 1 5  1 4 2

3 5 9  2 8 8 48.  1 1 6  7 2 2

1 1 3  5 4 6 49.  1 1 2  3 3 4

5 2 8  1 6 3 50.  1 1 7  2 3 4

2 3 6  7 3 4 51.  1 7 8  9 2 8

4 9 3  1 5 10 52.  5 3 6  2 6 4

1 5

3 6

53. What is twice the sum of 2 and ?

1 4

3 4

55. Add 5 to the sum of  and 2.

7 9

2 9

54. Find 3 times the difference of 1 and .

7 8

1 2

56. Subtract  from the product of 2 and 3.

185

186

C

Chapter 2 Fractions and Mixed Numbers

Applying the Concepts

57. Tri-cities The Google Earth image shows a right

58. Tri-cities The Google Earth image shows a right

triangle between three cities in Colorado. If the dis-

triangle between three cities in California. If the dis-

tance between Edgewater and Denver is 4 miles, and

 miles, and tance between Pomona and Ontario is 5 10

the distance between Denver and North Washington is

the distance between Ontario and Upland is 35 miles,

1

7

3

22 miles, what is the area of the triangle created by the

what is the area of the triangle created by the three

three cities?

cities?

North Washington

Upland

2.5 miles 3.6 miles

Edgewater

Denver

4 miles

Pomona

59. Manufacturing A dress manufacturer usually buys two 1

1

rolls of cloth, one of 32 2 yards and the other of 25 3

Ontario

5.7 miles

60. Body Temperature Suppose your normal body tempera3

ture is 98 5° Fahrenheit. If your temperature goes up

yards, to fill his weekly orders. If his orders double one

1 3 5°

4

week, how much of the cloth should he order? (Give

your temperature on Tuesday?

on Monday and then down 15° on Tuesday, what is

the total yardage.)

Maintaining Your Skills These problems review the four basic operations with fractions from this chapter. Perform the indicated operations. 3 4

8 9

61.   

3 7

2 7

65.   

5 6

2 3

62. 8  

6 7

63.   4

9 14

66.   

2 9

67. 10  

7 8

14 24

2 3

3 5

64.   

68.   

Chapter 2 Summary Definition of Fractions [2.1] EXAMPLES a A fraction is any number that can be written in the form , where a and b are b numbers and b is not 0. The number a is called the numerator, and the number b

1. Each of the following is a fraction: 1 3 8 7 , , ,  2 4 1 3

is called the denominator.

Properties of Fractions [2.1] Multiplying the numerator and the denominator of a fraction by the same nonzero number will produce an equivalent fraction. The same is true for dividing the numerator and denominator by the same nonzero number. In symbols the properties look like this: If a, b, and c are numbers and b and c are not 0, then Property 1

a ac     b bc

Property 2

3 4 fraction with denominator 12.

2. Change  to an equivalent 9 3 33      12 4 43

ac a     b bc

Fractions and the Number 1 [2.1] 5 1

a   a 1

and

a   1 a

5 5

3.   5,   1

If a represents any number, then (where a is not 0)

Reducing Fractions to Lowest Terms [2.2] To reduce a fraction to lowest terms, factor the numerator and the denominator, and then divide both the numerator and denominator by any factors they have in

90 588

 2 335  22 377 35   277

4.   

common.

15   98

Multiplying Fractions [2.3] 3 5

4 7

34 57

12 35

5.       

To multiply fractions, multiply numerators and multiply denominators.

The Area of a Triangle [2.3] 6. If the base of a triangle is 10

The formula for the area of a triangle with base b and height h is

inches and the height is 7 inches, then the area is 1 A  bh 2 1    10  7 2

h 1 A   bh 2

57  35 square inches

b Chapter 2

Summary

187

188

Chapter 2 Fractions and Mixed Numbers

Reciprocals [2.4] 2

3

Any two numbers whose product is 1 are called reciprocals. The numbers 3 and 2 are reciprocals, because their product is 1.

Division with Fractions [2.4] 3 8

1 3

3 8

3 1

9 8

7.         

To divide by a fraction, multiply by its reciprocal. That is, the quotient of two fractions is defined to be the product of the first fraction with the reciprocal of the second fraction (the divisor).

Least Common Denominator (LCD) [2.5] The least common denominator (LCD) for a set of denominators is the smallest number that is exactly divisible by each denominator.

Addition and Subtraction of Fractions [2.5] 1 8

3 8

13 8

8.      4   8

To add (or subtract) two fractions with a common denominator, add (or subtract) numerators and use the common denominator. In symbols: If a, b, and c are numbers with c not equal to 0, then a b ab       c c c

1   2

and

a b ab       c c c

Additional Facts about Fractions 1. In some books fractions are called rational numbers. 2. Every whole number can be written as a fraction with a denominator of 1. 3. The commutative, associative, and distributive properties are true for fractions. 2

4. The word of as used in the expression “3 of 12” indicates that we are to multiply

2  3

and 12.

5. Two fractions with the same value are called equivalent fractions.

Mixed-Number Notation [2.6] A mixed number is the sum of a whole number and a fraction. The  sign is not 2

shown when we write mixed numbers; it is implied. The mixed number 4 3 is actually the sum 4 

2 . 3

Chapter 2

189

Summary

Changing Mixed Numbers to Improper Fractions [2.6]

342 3

2 3

14 3

9. 4     m

m

To change a mixed number to an improper fraction, we write the mixed number

Mixed number

Improper fraction

showing the  sign and add as usual. The result is the same if we multiply the denominator of the fraction by the whole number and add what we get to the numerator of the fraction, putting this result over the denominator of the fraction.

Changing an Improper Fraction to a Mixed Number [2.6]

14 3

10. Change  to a mixed number.

Quotient 2 14   4 3 3

n

fraction part is the remainder over the divisor.

4  4 31 12 

n

the numerator. The quotient is the whole-number part of the mixed number. The

88n

To change an improper fraction to a mixed number, divide the denominator into

2

Divisor

Remainder

Multiplication and Division with Mixed Numbers [2.7]

1 3

3 4

7 3

7 4

1 12

49 12

11. 2  1        4

To multiply or divide two mixed numbers, change each to an improper fraction and multiply or divide as usual.

n

To add or subtract two mixed numbers, add or subtract the whole-number parts

4 4 4 3  3  3 9 9 9 2 23 6  2   2   2 3 33 9

and the fraction parts separately. This is best done with the numbers written in

10 1 5  6 9 9

columns.

888888n

Common denominator

8n

12.

88

Addition and Subtraction with Mixed Numbers [2.8]

Add fractions Add whole numbers

Borrowing in Subtraction with Mixed Numbers [2.8]

13.

1 4  3

2 4  6

8 3 6

5 5 5  1   1   1 6 6 6

It is sometimes necessary to borrow when doing subtraction with mixed numbers. We always change to a common denominator before we actually borrow.

3 1 2  2 6 2

Complex Fractions [2.9] 14. A fraction that contains a fraction in its numerator or denominator is called a complex fraction.

 

1

 

1 6 4  3 4  3    5 5 2  6 6 2  6 1

6  4  6  3   5 6  2  6  6 24  2

  12  5 26

5

   7 37

190

Chapter 2 Fractions and Mixed Numbers

COMMON MISTAKES 1. The most common mistake when working with fractions occurs when we try to add two fractions without using a common denominator. For example, 2 4 24       3 5 35 If the two fractions we are trying to add don’t have the same denominators, then we must rewrite each one as an equivalent fraction with a common denominator. We never add denominators when adding fractions.

Note: We do not need a common denominator when multiplying fractions.

2. A common mistake made with division of fractions occurs when we multiply by the reciprocal of the first fraction instead of the reciprocal of the divisor. For example, 2 5 3 5        3 6 2 6 Remember, we perform division by multiplying by the reciprocal of the divisor (the fraction to the right of the division symbol).

3. If the answer to a problem turns out to be a fraction, that fraction should always be written in lowest terms. It is a mistake not to reduce to lowest terms.

4. A common mistake when working with mixed numbers is to confuse 2

mixed-number notation for multiplication of fractions. The notation 3 5 does not mean 3 times

2 . 5

It means 3 plus

2 . 5

5. Another mistake occurs when multiplying mixed numbers. The mistake occurs when we don’t change the mixed number to an improper fraction before multiplying and instead try to multiply the whole numbers and fractions separately. Like this: 1 1 1 1 2  3  (2  3)     2 3 2 3





Mistake

1  6   6 1  6 6 Remember, the correct way to multiply mixed numbers is to first change to improper fractions and then multiply numerators and multiply denominators. This is correct: 1 1 5 10 50 2 1 2  3        8  8 2 3 2 3 6 6 3

Correct

Chapter 2

Review

Reduce each of the following fractions to lowest terms. [2.2] 6 8

12 36

1. 

110 70

2. 

45 75

3. 

4. 

Multiply the following fractions. (That is, find the product in each case, and reduce to lowest terms.) [2.3] 1 5

96 25

80 3 27 20

 

5. (5x)

15 98

35 54

3 5

7.     

6.  

2 3

8.   75  

Find the following quotients. (That is, divide and reduce to lowest terms.) [2.4] 8 9

4 3

15 36

9 10

9.   

10.   3

10 9

11.   

18 49

36 28

9 52

5 78

12.   

Perform the indicated operations. Reduce all answers to lowest terms. [2.5] 6 8

2 8

13.   

11 126

9 10

11 10

3 10

7 25

1 2

14.   

5 84

17.   

15. 3  

16.   

3 4

18.     

Change to improper fractions. [2.6] 5 8

2 3

19. 3

20. 7

Change to mixed numbers. [2.6] 15 4

110 8

21. 

22. 

Perform the indicated operations. [2.7, 2.8] 1 4

7 8

23. 2  3

3 5

24. 4  2 

1 2

4 5

25. 6  2  

1 5

2 5

2 3

26. 3  4

1 4

28. 5  2

Chapter 2

Review

27. 8  9

1 3

8 9

Simplify each of the following as much as possible. [2.9] 1

 3

29. 3  2 4



1 2

3 4



1 2

3 4



30. 2   2  

191

192

Chapter 2 Fractions and Mixed Numbers

Simplify each complex fraction as much as possible. [2.9] 2 1   3 31.  2 1   3

3 3   4 32.  3 3   4

7 1    8 2 33.  1 1    4 2

1

35. Defective Parts If 1 of the items in a shipment of 200 0 items are defective, how many are defective? [2.3]

1 1 2  3 8 3 34.  1 1 1   5  6 4

36. Number of Students If 80 students took a math test and 3  4

of them passed, then how many students passed the

test? [2.3]

1

3

37. Translating What is 3 times the sum of 2 4 and 4? [2.9]

5

1

2

38. Translating Subtract 6 from the product of 12 and 3. [2.9]

1

39. Cooking If a recipe that calls for 2 2 cups of flour will make 48 cookies, how much flour is needed to make 36

3

40. Length of Wood A piece of wood 10 4 inches long is divided into 6 equal pieces. How long is each piece? [2.7]

cookies? [2.7]

1

41. Cooking A recipe that calls for 3 2 tablespoons of oil is

1

42. Sheep Feed A rancher fed his sheep 10 2 pounds of feed 3

1

tripled. How much oil must be used in the tripled

on Monday, 9 4 pounds on Tuesday, and 12 4 pounds on

recipe? [2.7]

Wednesday. How many pounds of feed did he use on these 3 days? [2.8]

43. Find the area and the perimeter of the triangle below. [2.7, 2.8]

44. Comparing Area On April 3, 2000, USA TODAY changed the size of its paper. Previous to this date, each page of 1

1

the paper was 13 2 inches wide and 224 inches long. The new paper size is

10

2 5

ft 4 ft

5 ft

1 14

1

inches narrower and 2 inch

longer. [2.7, 2.8]

a. What was the area of a page previous to April 3, 2000?

3 12 5

ft

b. What is the area of a page after April 3, 2000? c. What is the difference in the areas of the two page sizes?

Old size New size

Chapter 2

Cumulative Review

Simplify.

1. (6  2)  (3  6)

2.

3. 1985  141

99 144 81  49

5 8

4. 13  (9  4)

1 4

1 2

7.   

8. 112

9. 5280

12.

11. 3  102  5  10  4

3 8

6 16

4 5

14.   

2 5

17. 3  

13.   

3

3 4 8 22.  2 5  3

23.     



1 4

1 5



25. 2 1  

2

1

3

21. 121  11  11

20. 

3

2

4 2

19. 

5

3

18.   

104 33

11 77

 8 

15. 32  42

1 2

16. 10  

1 3

5 12

6. 17  9

 26

10. 9050(373)

1 2

13 16

3 8

5.   

2 25



3 11

4 125

1 2

24. 6    

26. Round the following numbers to the nearest ten, then add. 747 116  222  2 1 3 9

3 4

27. Find the sum of , , and .

7 9

1 4

29. Find  of 3.

3

28. Write the fraction 1 as an equivalent fraction with a 3 denominator of 39x.

30. Find the sum of 12 times 2 and 19 times 4.

Chapter 2

Cumulative Review

193

194

Chapter 2 Fractions and Mixed Numbers 32. Place either  or between the following numbers.

31. Find the area of the figure:

1

1

2 2

22 in.

3

2

6 in. 10 in.

11 in. 5 in. 12 in.

111 19

33. Change  to an improper fraction.

34. Medical Costs The table below shows the average yearly cost of visits to the doctor. Fill in the last column of the table by rounding each cost to the nearest hundred. MEDICAL COSTS

35. Reduce to lowest terms.

Year

Average Annual Cost

1990 1995 2000 2005

$583 $739 $906 $1,172

Cost to the Nearest Hundred

36. Find the area of the figure below:

14  49

4 cm

11 cm

4 5

4 9

37. Add  to half of .

38. Neptune’s Diameter The planet Neptune has an

39. Photography A photographer buys one roll of 36-

equatorial diameter of about 30,760 miles. Write out

exposure 400-speed film and two rolls of 24-exposure

Neptune’s diameter in words and expanded form.

100-speed film. She uses 6 of each type of film. How

5

many pictures did she take?

Chapter 2

Test

1. Each circle below is divided into 8 equal parts. Shade each circle to represent the fraction below the circle.

2. Reduce each fraction to lowest terms. a.

10  15 130 50

b. 

3 – 8

1 – 8

5 – 8

7 – 8

Find each product, and reduce your answer to lowest terms. 3 5

48 49

3. (30)

35 50

6 18

4.     

Find each quotient, and reduce your answer to lowest terms. 15 16

5 18

4 5

5.   

6.   8

Perform the indicated operations. Reduce all answers to lowest terms. 3 10

1 10

7.   

3 5

9. 4  

5 6

2 9

5 8

2 8

3 10

2 5

8.   

10.   

1 4

11.     

2 7

12. Change 5 to an improper fraction.

Chapter 2

Test

195

196

Chapter 2 Fractions and Mixed Numbers 43 5

1 4

13. Change  to a mixed number.

14. Multiply: 8  3

Perform the indicated operations. 1 3

1 3

15. 6  1

3 8

17. 5  1

1 6

1 2

11 2    12 3 20.  1 1    6 3

16. 7  2

1 2

Simplify each of the following as much as possible. 1

 4



18. 4  3 4

1 3



2 3

1

21. Number of Grapefruit If 3 of a shipment of 120 grapefruit is spoiled, how many grapefruit are spoiled?

2

23. Cooking A recipe that calls for 4 3 cups of sugar is doubled. How much sugar must be used in the doubled recipe?

25. Find the area and the perimeter of the triangle below.

2

1

8 3 ft

1 6



19. 2   3  

5 3 ft 5 ft

1

9 3 ft

1

22. Sewing A dress that is 316 inches long is shortened by 2 3 3

inches. What is the new length of the dress?

2

24. Length of Rope A piece of rope 15 3 feet long is divided into 5 equal pieces. How long is each piece?

Chapter 2 Projects FRACTIONS AND MIXED NUMBERS

GROUP PROJECT Recipe Number of People Time Needed Equipment Background

1. Heat oven to 375°. Line several baking sheets

2

with parchment paper, and set aside.

5 minutes

2. Combine butter and both sugars in the bowl

Pencil and paper

of an electric mixer fitted with the paddle at-

Here is Martha Stewart’s recipe for chocolate

tachment, and beat until light and fluffy. Add

chip cookies.

vanilla, and mix to combine. Add egg, and continue beating until well combined.

Chocolate Chip Cookies

3. In a medium bowl, whisk together the flour,

Makes 2 dozen You can substitute bittersweet chocolate for half of the semisweet chocolate chips.

ture

on a prepared baking sheet. Repeat with re-

1/2 cup granulated sugar

maining dough, placing scoops 3 inches

1 teaspoon pure vanilla extract

apart. Bake until just brown around the

1 large egg, room temperature

edges, 16 to 18 minutes, rotating the pans

2 cups all-purpose flour

between the oven shelves halfway through

1/2 teaspoon baking soda

baking. Remove from the oven, and let cool

1/2 teaspoon salt semisweet

chocolate,

coarsely

chopped, or one 12-ounce bag semisweet chocolate chips

Procedure

Rewrite the recipe to make 3 dozen cookies by 1 multiplying the quantities by 1. 2 cups (

chips.

4. Scoop out 2 tablespoons of dough, and place

1 1/2 cups packed light-brown sugar

ounces

gredients to the butter mixture. Mix on low speed until just combined. Stir in chocolate

1 cup (2 sticks) unsalted butter, room tempera-

12

baking soda, and salt. Slowly add the dry in-

sticks) unsalted butter,

room temperature cups packed light-brown sugar cups granulated sugar teaspoons pure vanilla extract

slightly before removing cookies from the baking sheets. Store in an airtight container at room temperature for up to 1 week. large eggs, room temperature cups all-purpose flour teaspoons baking soda teaspoons salt ounces semisweet chocolate, coarsely chopped, or

12-ounce bags semi-

sweet chocolate chips

Chapter 2

Projects

197

RESEARCH PROJECT Sophie Germain The photograph at the right shows the street sign in Paris named for the French mathematician Sophie Germain (1776-1831). Among her contributions to mathematics is her work with prime numbers. In this chapter we had an intronumbers, including the prime numbers. Within the prime numbers themselves, there are still further classifications. In fact, a Sophie Germain prime is a prime number P, for which both P and 2P  1 are primes. For example, the prime number 2 is the first Sophie Germain prime because both 2 and 2  2  1  5 are prime numbers. The next Germain prime is 3 because both 3 and 2  3  1  7 are primes. Sophie Germain was born on April 1, 1776, in Paris, France. She taught herself mathematics by reading the books in her father’s library at home. Today she is recognized most for her work in number theory, which includes her work with prime numbers. Research the life of Sophie Germain. Write a short essay that includes information on her work with prime numbers and how her results contributed to solving Fermat’s Theorem almost 200 years later.

198

Chapter 2 Whole Numbers

Cheryl Slaughter

ductory look at some of the classifications for

A Glimpse of Algebra In algebra, we add and subtract fractions in the same way that we have added and subtracted fractions in this chapter. For example, consider the expression 2 x    3 3 The two fractions have the same denominator. So to add these fractions, all we have to do is add the numerators to get x  2. The denominator of the sum is the common denominator 3: x2 x 2      3 3 3 Here are some further examples.

PRACTICE PROBLEMS

EXAMPLE 1

Add or subtract as indicated.

x 5

x5 8

4 5

a.   

3 8

b.   

4x 10

1. Add or subtract as indicated: 3x 10

c.   

5 x

3 x

d.   

5 6

x 6

a.    x3 7

1 7

b.   

SOLUTION

In each case the denominators are the same. We add or subtract

the numerators and write the sum or difference over the common denominator. x 5

d.   

a.      x5 8

x2 8

x53 8

3 8

3 x

9 x

x4 5

4 5

4x 4

9x 4

c.   

b.        4x 10

3x 10

4x  3x 10

7x 10

c.        5 x

3 x

53 x

8 x

d.        To add or subtract fractions that do not have the same denominator, we must first find the LCD. We then change each fraction to an equivalent fraction that has the LCD for its denominator. Finally, when all that has been done, we add or subtract the numerators and put the result over the common denominator.

EXAMPLE 2 SOLUTION

x 1 Add:    3 2 The LCD for 3 and 2 is 6. We multiply the numerator and the de-

Note

Remember, the LCD is the least common denominator. It is the smallest expression that is divisible by each of the denominators.

x 3

1 5

2. Add:   

nominator of the first fraction by 2, and the numerator and the denominator of the second fraction by 3, to change each fraction to an equivalent fraction with the LCD for a denominator. We then add the numerators as usual. Here is how it looks: 13 1 x2 x        32 23 3 2 3 2x     6 6 2x  3   6

Change to equivalent fractions. Also, x  2 is the same as 2x, because multiplication is commutative. Add the numerators

Answers x5 6

1. a.  12 x

d. 

A Glimpse of Algebra

x2 7

b. 

13x 4

c. 

5x  3 15

2. 

199

200

Chapter 2 Fractions and Mixed Numbers

EXAMPLE 3

2 3

5 x

3. Add:   

SOLUTION

Note

In Examples 3 and 4, it is understood that x cannot be 0. Do you know why?

4 2 Add:    x 3 The LCD for x and 3 is 3x. We multiply the numerator and the de-

nominator of the first fraction by 3, and the numerator and the denominator of the second fraction by x, to get two fractions with the same denominator. We then add the numerators: 2x 2 43 4       x 3 x3 3x

Change to equivalent fractions

2x 12     3x 3x 12  2x   3x

1 2

3 x

1 5

4. Add:     

Add the numerators

EXAMPLE 4 SOLUTION

1 5 1 Add:      2 x 3 The LCD for 2, x, and 3 is 6x. 1  2x 1 1  3x 56 1 5            2  3x x6 3  2x 2 x 3

Change to equivalent fractions

2x 3x 30       6x 6x 6x 5x  30   6x

Add the numerators

In this chapter we changed mixed numbers to improper fractions. For example, 4

the mixed number 35 can be changed to an improper fraction as follows: 35 4 4 4 15 4 19 3   3               15 5 5 5 5 5 5 x A similar kind of problem in algebra would be to add 2 and  . 8 5. Add or subtract as indicated. a.

EXAMPLE 5

x 3  8

x 8

a. 2  

a 4

b. 1   c.

2 6  x

d.

2 x  3

Add or subtract as indicated.

SOLUTION

a 2

3 5

3 x

b. 1  

c. 5  

d. x  

We can think of each whole number and the letter x in part (d) as a

fraction with denominator 1. In each case we multiply the numerator and the denominator of the first number by the denominator of the fraction. 16  x 8

x 8

28 18

x 8

16 8

a 2

12 12

a 2

2 2

a 2

2a 2

3 x

5x 1x

3 x

5x x

3 x

5x  3 x

3 5

x5 15

3 5

5x 5

3 5

5x  3 5

x 8

a. 2             b. 1             c. 5            

Answers 3.

15  2x  3x 24  x 8

5. a.  6x  2 x

c. 

4.

7x  30  10x 4a 4

b.  3x  2 3

d. 

d. x            

A Glimpse of Algebra Problems

201

A Glimpse of Algebra Problems Add or subtract as indicated. x 4

3 4

x 8

1.   

2x 8

5x 8

x6 5

5 8

2.   

9x 7

5.   

4 5

3.   

3x 7

6 x

6.   

4 x

x1 3

3 x

7.   

2 3

4.   

7 x

8.   

For each sum or difference, find the LCD, change to equivalent fractions, and then add or subtract numerators as indicated.

9.   

x 2

1 3

10.   

x 6

3 4

11.   

x 2

1 4

12.   

3 x

3 4

14.   

2 x

1 3

15.   

4 5

1 x

16.   

1 3

2 x

1 5

1 x

1 2

1 x

13.   

1 4

17.     

1 3

18.     

1 4

19.     

x 3

1 6

3 4

1 x

1 3

1 x

1 6

20.     

202

Chapter 2 Fractions and Mixed Numbers

Add or subtract as indicated.

21. 3  

x 4

22. 2  

25. 4  

a 7

26. 6  

29. 8  

3 x

30. 7  

3 4

34. x  

4a 7

38. a  

33. x  

37. a  

x 7

23. 5  

x 2

24. 6  

a 4

27. 1  

9 x

31. 2  

5 6

35. x  

3a 5

39. 2x  

2a 5

28. 3  

5 x

32. 3  

2x 9

36. x  

3x 4

x 8

4a 9

1 x

3x 5

2x 5

40. 3x  

3

Decimals

Chapter Outline 3.1 Decimal Notation and Place Value 3.2 Addition and Subtraction with Decimals 3.3 Multiplication with Decimals; Circumference and Area of a Circle 3.4 Division with Decimals 3.5 Fractions and Decimals, and the Volume of a Sphere 3.6 Square Roots and the Pythagorean Theorem

Introduction The 2000 Summer Olympic Games in Sydney, Australia, featured more than 10,000 athletes competing from 199 countries. The image above shows many of the venues as they appear in Google Earth in 2008, almost eight years after the 2000 Olympics. The chart below shows the top four finishes in the 400-meter Freestyle swimming event in Sydney.

400-meter Freestyle Swimming Final times for the 400-meter freestyle swim

Ian Thorpe

3:40.59

Massimiliano Rosolino

3:43.40

Klete Keller

3:47.00

Emiliano Brembilla

3:47.01 Source: espn.com

The times in the chart are in minutes and seconds, accurate to the nearest hundredth of a second. In this chapter we work with numbers like these to obtain a good working knowledge of the decimal numbers we see everywhere around us.

203

Chapter Pretest The pretest below contains problems that are representative of the problems you will find in the chapter.

1. Write the number 4.013 in words.

2. Write 12.09 as a mixed number.

3. Write thirty-four hundredths as a decimal number.

4. Write  as a decimal

5. Write the following numbers in order from smallest

6. Change 0.85 to a fraction, and then reduce to low-

to largest.

21 50

est terms.

0.04, 0.4, 0.51, 0.5, 0.45, 0.41 Perform the indicated operations.

7. 7.36  8.05

8. 20.3  15.09

9. 3.6  2.7

11. 321 3 1 .8 4 

10. 56.78(10)

12. 1.04  0.12

Simplify each expression as much as possible.

13. 36   2100 

14.

 25  144

15. 180 

Getting Ready for Chapter 3 The problems below review material covered previously that you need to know in order to be successful in Chapter 3. If you have any difficulty with the problems here, you need to go back and review before going on to Chapter 3. Simplify.

1. 25,430  2,897  379,600

2. 39,812  14,236

3. 2,000  1,564

4. 800  137

5. 305  436

6. 13(56)

7. 480  12(32)2

8. 384  4

9. 49,896  27

3 2 4 5

 

13.  

10. 5,974  20

1 2

5

1

 8  4 

14.  2 1

204

Chapter 3 Decimals

2

12. 

15. Round 9,235 to the

16. Reduce: 

nearest hundred.

Factor into a product of prime factors.

17. 48

1

4

11. 52  72

18. 180

38 100

Decimal Notation and Place Value

3.1 Objectives A Understand place value for decimal

Introduction . . . In this chapter we will focus our attention on decimals. Anyone who has used money in the United States has worked with decimals already. For example, if you have been paid an hourly wage, such as

numbers.

B

Write decimal numbers in words and with digits.

C

Convert decimals to fractions and fractions to decimals.

D E

Round a decimal number.

m8

$6.25 per hour

Decimal point

Solve applications involving decimals.

you have had experience with decimals. What is interesting and useful about decimals is their relationship to fractions and to powers of ten. The work we

Examples now playing at

have done up to now—especially our work with fractions—can be used to de-

MathTV.com/books

velop the properties of decimal numbers.

A Place Value In Chapter 1 we developed the idea of place value for the digits in a whole number. At that time we gave the name and the place value of each of the first seven columns in our number system, as follows:

Millions Column

Hundred Thousands Column

Ten Thousands Column

Thousands Column

Hundreds Column

Tens Column

Ones Column

1,000,000

100,000

10,000

1,000

100

10

1

As we move from right to left, we multiply by 10 each time. The value of each column is 10 times the value of the column on its right, with the rightmost column being 1. Up until now we have always looked at place value as increasing by a factor of 10 each time we move one column to the left: Ten Thousands

Thousands

Hundreds

Tens

Ones

10,000 m8888888888888 1,000 m888888888888888 100 m888888888888888 10 m88888888888 1 Multiply by 10

Multiply by 10

Multiply by 10

Multiply by 10

To understand the idea behind decimal numbers, we notice that moving in the opposite direction, from left to right, we divide by 10 each time: Ten Thousands

Thousands

Hundreds

Tens

Ones

10,000 8888888888888n 1,000 888888888888888n 100 888888888888888n 10 88888888888n 1 Divide by 10

Divide by 10

Divide by 10

Divide by 10

If we keep going to the right, the next column will have to be 1 1  10   10

Tenths

The next one after that will be 1 1 1 1   10       10 10 10 100

Hundredths

3.1 Decimal Notation and Place Value

205

206

Chapter 3 Decimals After that, we have 1 1 1 1   10       100 100 10 1,000

Thousandths

We could continue this pattern as long as we wanted. We simply divide by 10 to move one column to the right. (And remember, dividing by 10 gives the same re1

.) sult as multiplying by 1 0 To show where the ones column is, we use a decimal point between the ones

1  10

1  100

1  1,000

Hundred Thousandths

.

Ten Thousandths

1

Thousandths

10

Hundredths

Ones

100

Tenths

Tens

1,000

m8

Because the digits to the right of the decimal point have fractional place values, numbers with digits to the right of the decimal point are called decimal fractions. In this book we will also call them decimal numbers, or simply decimals for short.

Hundreds

Note

Thousands

column and the tenths column.

1  10,000

1  100,000

Decimal point

The ones column can be thought of as the middle column, with columns larger than 1 to the left and columns smaller than 1 to the right. The first column to the right of the ones column is the tenths column, the next column to the right is the hundredths column, the next is the thousandths column, and so on. The decimal point is always written between the ones column and the tenths column. We can use the place value of decimal fractions to write them in expanded form.

PRACTICE PROBLEMS 1. Write 785.462 in expanded form.

EXAMPLE 1 SOLUTION

Write 423.576 in expanded form. 5 7 6 423.576  400  20  3       10 100 1,000

B Writing Decimals with Words 2. Write in words. a. 0.06 b. 0.7 c. 0.008

3. Write in words. a. 5.06 b. 4.7 c. 3.008

Note

Sometimes we name decimal fractions by simply reading the digits from left to right and using the word “point” to indicate where the decimal point is. For example, using this method the number 5.04 is read “five point zero four.” Answers 1–3. See solutions section.

EXAMPLE 2

Write each number in words.

a. 0.4 b. 0.04 c. 0.004 SOLUTION a. 0.4 is “four tenths.” b. 0.04 is “four hundredths.” c. 0.004 is “four thousandths.” When a decimal fraction contains digits to the left of the decimal point, we use the word “and” to indicate where the decimal point is when writing the number in words.

EXAMPLE 3

Write each number in words.

a. 5.4 b. 5.04 c. 5.004 SOLUTION a. 5.4 is “five and four tenths.” b. 5.04 is “five and four hundredths.” c. 5.004 is “five and four thousandths.”

207

3.1 Decimal Notation and Place Value

EXAMPLE 4 SOLUTION

Write 3.64 in words.

The number 3.64 is read “three and sixty-four hundredths.” The

4. Write in words. a. 5.98 b. 5.098

place values of the digits are as follows: 3

.

6

4

m8

6 tenths

8 m8

m8

3 ones

4 hundredths

We read the decimal part as “sixty-four hundredths” because 6 4 60 4 64 6 tenths  4 hundredths           10 100 100 100 100

EXAMPLE 5 SOLUTION

Write 25.4936 in words.

5. Write 305.406 in words.

Using the idea given in Example 4, we write 25.4936 in words as

“twenty-five and four thousand, nine hundred thirty-six ten thousandths.”

C Converting Between Fractions and Decimals In order to understand addition and subtraction of decimals in the next section, we need to be able to convert decimal numbers to fractions or mixed numbers.

EXAMPLE 6

Write each number as a fraction or a mixed number. Do

not reduce to lowest terms.

a. 0.004 SOLUTION

b. 3.64

c. 25.4936

a. Because 0.004 is 4 thousandths, we write

6. Write each number as a fraction or a mixed number. Do not reduce to lowest terms. a. 0.06 b. 5.98 c. 305.406

Three digits after the decimal point

88 m

m8

4 0.004   1,000

Three zeros

b. Looking over the work in Example 4, we can write

Two digits after the decimal point

88 m

m8

64 3.64  3  100

Two zeros

c. From the way in which we wrote 25.4936 in words in Example 5, we have

Four digits after the decimal point

88 m

m8

4936 25.4936  25  10,000

Four zeros

D Rounding Decimal Numbers The rule for rounding decimal numbers is similar to the rule for rounding whole numbers. If the digit in the column to the right of the one we are rounding to is 5 or more, we add 1 to the digit in the column we are rounding to; otherwise, we leave it alone. We then replace all digits to the right of the column we are rounding to with zeros if they are to the left of the decimal point; otherwise, we simply delete them. Table 1 illustrates the procedure.

Answers 4–5. See solutions section. 6

6. a.  100

98

b. 5  100 406

c. 305  1,000

208

Chapter 3 Decimals

TABLE 1

Rounded to the Nearest Number

Whole Number

Tenth

Hundredth

25 2 1 14 1

24.8 2.4 1.0 14.1 0.5

24.79 2.39 0.98 14.09 0.55

24.785 2.3914 0.98243 14.0942 0.545

7. Round 8,935.042 to the nearest: a. hundred b. hundredth

EXAMPLE 7 SOLUTION

Round 9,235.492 to the nearest hundred.

The number next to the hundreds column is 3, which is less than 5.

We change all digits to the right to 0, and we can drop all digits to the right of the decimal point, so we write 9,200 8. Round 0.05067 to the nearest: a. ten thousandth b. tenth

EXAMPLE 8 SOLUTION

Round 0.00346 to the nearest ten thousandth.

Because the number to the right of the ten thousandths column is

more than 5, we add 1 to the 4 and get 0.0035

E Applications with Decimals 9. Round each number in the bar chart to the nearest tenth of a dollar

EXAMPLE 9

The bar chart below shows some ticket prices for a recent

major league baseball season. Round each ticket price to the nearest dollar.

$24.05

Baseball's ticket prices (average for all seats)

25 20 $14.91

15 10

$8.46

5 0 Least expensive

SOLUTION

League average

Most expensive

Using our rule for rounding decimal numbers, we have the follow-

ing results: Least expensive: $8.46 rounds to $8 League average: $14.91 rounds to $15 Most expensive: $24.05 rounds to $24

Answers 7. a. 8,900 b. 8,935.04 8. a. 0.0507 b. 0.1 9. Least expensive, $8.50; league average, $14.90; most expensive, $24.10

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Write 754.326 in expanded form. 1 3 7 2. Write 400  70  5       in decimal form. 10 100 1,000 3. Write seventy-two and three tenths in decimal form.

3.1 Problem Set

209

Problem Set 3.1 B Write out the name of each number in words. [Examples 2–5] 1. 0.3

2. 0.03

3. 0.015

4. 0.0015

5. 3.4

6. 2.04

7. 52.7

8. 46.8

C Write each number as a fraction or a mixed number. Do not reduce your answers. [Example 6] 9. 405.36

13. 1.234

10. 362.78

11. 9.009

12. 60.06

14. 12.045

15. 0.00305

16. 2.00106

A Give the place value of the 5 in each of the following numbers. [Example 1] 17. 458.327

18. 327.458

19. 29.52

20. 25.92

21. 0.00375

22. 0.00532

23. 275.01

24. 0.356

25. 539.76

26. 0.123456

B Write each of the following as a decimal number. 27. Fifty-five hundredths

28. Two hundred thirty-five ten thousandths

29. Six and nine tenths

30. Forty-five thousand and six hundred twenty-one thousandths

31. Eleven and eleven hundredths

32. Twenty-six thousand, two hundred forty-five and sixteen hundredths

33. One hundred and two hundredths

34. Seventy-five and seventy-five hundred thousandths

35. Three thousand and three thousandths

36. One thousand, one hundred eleven and one hundred eleven thousandths

210

Chapter 3 Decimals

For each pair of numbers, place the correct symbol,  or , between the numbers.

37. a. 0.02 b. 0.3

38. a. 0.45 b. 0.5

0.2 0.032

39. Write the following numbers in order from smallest to

40. Write the following numbers in order from smallest to

largest. 0.02

0.5 0.56

largest.

0.05 0.025

0.052

0.005

0.002

41. Which of the following numbers will round to 7.5? 7.451 7.449 7.54

0.2

0.02

0.4

0.04

0.42

0.24

42. Which of the following numbers will round to 3.2?

7.56

3.14999

3.24999

3.279

3.16111

C Change each decimal to a fraction, and then reduce to lowest terms. 43. 0.25

44. 0.75

45. 0.125

46. 0.375

47. 0.625

48. 0.0625

49. 0.875

50. 0.1875

Estimating For each pair of numbers, choose the number that is closest to 10. 51. 9.9 and 9.99

52. 8.5 and 8.05

53. 10.5 and 10.05

54. 10.9 and 10.99

Estimating For each pair of numbers, choose the number that is closest to 0. 55. 0.5 and 0.05

56. 0.10 and 0.05

57. 0.01 and 0.02

58. 0.1 and 0.01

D Complete the following table. [Examples 7, 8] Rounded to the Nearest Number

59.

47.5479

60.

100.9256

61.

0.8175

62.

29.9876

63.

0.1562

64.

128.9115

65. 2,789.3241 66.

0.8743

67.

99.9999

68.

71.7634

Whole Number

Tenth

Hundredth

Thousandth

3.1 Problem Set

E

Applying the Concepts

211

[Example 9]

100 Meters At the 1928 Olympic Games in Amsterdam, the winning time for the women’s 100 meters was 12.2 seconds. Since then, the time has continued to get faster. The chart shows the fastest times for the women’s 100 meters in the Olympics. Use the chart to answer Problems 69 and 70.

69. What is the place value of the 3 in Christine Arron’s time in 1998?

Faster Than... 10.49 sec

Florence Griffith Joyner, 1988

10.65 sec

Marion Jones, 1998

70. Write Christine Arron’s time using words.

Christine Arron, 1998

10.73 sec

Merlene Ottey, 1996

10.74 sec

Source: www.tenmojo.com

71. Gasoline Prices The bar chart below was created from a

72. Speed and Time The bar chart below was created from

survey by the U.S. Department of Energy’s Energy Infor-

data given by Car and Driver magazine. It gives the

mation Administration during the month of May 2008.

minimum time in seconds for a Toyota Echo to reach

It gives the average price of regular gasoline for the

various speeds from a complete stop. Use the informa-

state of California on each Monday of the month. Use

tion in the chart to fill in the table.

the information in the chart to fill in the table. Speed (Miles per Hour)

PRICE OF 1 GALLON OF REGULAR GASOLINE

Time (Seconds)

30

Date

Price (Dollars)

40

5/5/08

50

5/12/08

60

5/19/08

70

5/26/08

80 90

25 20.6

4.099

20

4.000

Time (seconds)

Price (dollars)

4.100

3.952 3.903

3.919

3.900

15.4 15 11.6

6.2 5

3.800

5/5/08

5/12/08

5/19/08

Date

5/26/08

8.5

10 4.2 2.7

0 30

40

50

60

70

Speed (miles per hour)

80

90

212

Chapter 3 Decimals

73. Penny Weight If you have a penny dated anytime from

74. Halley’s Comet Halley’s comet was seen from the earth

1959 through 1982, its original weight was 3.11 grams.

during 1986. It will be another 76.1 years before it re-

If the penny has a date of 1983 or later, the original

turns. Write 76.1 in words.

weight was 2.5 grams. Write the two weights in words.

2.5

1g

1959-1982

g

NASA

3.1

1983 - present

75. Nutrition A 50-gram egg contains 0.15 milligram of ri-

76. Nutrition One medium banana contains 0.64 milligram of B6. Write 0.64 in words.

boflavin. Write 0.15 in words.

Getting Ready for the Next Section In the next section we will do addition and subtraction with decimals. To understand the process of addition and subtraction, we need to understand the process of addition and subtraction with mixed numbers. Find each of the following sums and differences. (Add or subtract.) 3 10

1 100

1 10

2 100

35 100

77. 4   2 

3 10

78. 5   2 

3 1,000

81. 5   6   7 

5 10

4 100

27 100

3 10

3 100

79. 8   2 

125 1,000

80. 6   2 

123 1,000

82. 4   6   7 

Maintaining Your Skills Write the fractions in order from smallest to largest. 3 8

83. 

3  16

3  4

3 4

3  10

84. 

1  4

5  4

1  2

Place the correct inequality symbol,  or between each pair of numbers. 3 8

85. 

5  6

9 10

86. 

10  11

1 12

87. 

1  13

3 4

88. 

5  8

Addition and Subtraction with Decimals Introduction . . . The chart shows the top finishing times for the women’s 400-meter race during the Sydney Olympics in 2000. In order to analyze the different finishing times, it is important that you are able to add and subtract decimals, and that is what we

3.2 Objectives A Add and subtract decimals. B Solve applications involving addition and subtraction of decimals.

will cover in this section.

Examples now playing at

Sydney Olympics The chart shows the top finishing times for the women’s 400-meter race during the Sydney Olympics.

Cathy Freeman

49.11

Lorraine Graham

49.58

Katharine Merry

49.72

Donna Fraser

49.79

MathTV.com/books

Source: espn.com

A Combining Decimals Suppose you are earning $8.50 an hour and you receive a raise of $1.25 an hour. Your new hourly rate of pay is $8.50  $1.25 $9.75 To add the two rates of pay, we align the decimal points, and then add in columns. To see why this is true in general, we can use mixed-number notation: 50 8.50  8  100 25  1.25  1  100 75 9   9.75 100 We can visualize the mathematics above by thinking in terms of money:

+

$

9

+

.

7

5

PRACTICE PROBLEMS 1. Change each decimal to a frac-

EXAMPLE 1 SOLUTION

Add by first changing to fractions: 25.43  2.897  379.6

We first change each decimal to a mixed number. We then write

each fraction using the least common denominator and add as usual:

3.2 Addition and Subtraction with Decimals

tion, and then add. Write your answer as a decimal. a. 38.45  456.073 b. 38.045  456.73

213

214

Chapter 3 Decimals

43 430 25.43  25   25  100 1,000 897 2.897  2   1,000

897 2 1,000

600 6  379.6  379   379  10 1,000 1,927 927 406   407   407.927 1,000 1,000 Again, the result is the same if we just line up the decimal points and add as if we were adding whole numbers: 25.430 2.897  379.600

Notice that we can fill in zeros on the right to help keep the numbers in the correct columns. Doing this does not change the value of any of the numbers.

407.927 n

88

Note: The decimal point in the answer is directly below the decimal points in the problem The same thing would happen if we were to subtract two decimal numbers. We can use these facts to write a rule for addition and subtraction of decimal numbers.

Rule To add (or subtract) decimal numbers, we line up the decimal points and add (or subtract) as usual. The decimal point in the result is written directly below the decimal points in the problem.

We will use this rule for the rest of the examples in this section.

2. Subtract: 78.674  23.431

EXAMPLE 2 SOLUTION

Subtract: 39.812  14.236

We write the numbers vertically, with the decimal points lined up,

and subtract as usual. 39.812  14.236 25.576

3. Add: 16  0.033  4.6  0.08

EXAMPLE 3 SOLUTION

Add: 8  0.002  3.1  0.04

To make sure we keep the digits in the correct columns, we can

write zeros to the right of the rightmost digits. 8  8.000 Writing the extra zeros here is really 3.1  3.100 equivalent to finding a common denominator 0.04  0.040 for the fractional parts of the original four

numbers—now we have a thousandths column in all the numbers This doesn’t change the value of any of the numbers, and it makes our task easier. Now we have 8.000 0.002 3.100 Answers 1. a. 494.523 b. 494.775 2. 55.243 3. 20.713

 0.040 11.142

215

3.2 Addition and Subtraction with Decimals

EXAMPLE 4 SOLUTION

Subtract: 5.9  3.0814

In this case it is very helpful to write 5.9 as 5.9000, since we will

4. Subtract: a. 6.7  2.05 b. 6.7  2.0563

have to borrow in order to subtract. 5.9000  3.0814 2.8186

EXAMPLE 5 SOLUTION

Subtract 3.09 from the sum of 9 and 5.472.

Writing the problem in symbols, we have

5. Subtract 5.89 from the sum of 7 and 3.567.

(9  5.472)  3.09  14.472  3.09  11.382

B Applications EXAMPLE 6

While I was writing this section of the book, I stopped to

have lunch with a friend at a coffee shop near my office. The bill for lunch was $15.64. I gave the person at the cash register a $20 bill. For change, I received four $1 bills, a quarter, a nickel, and a penny. Was my change correct?

SOLUTION

To find the total amount of money I received in change, we add:

6. If you pay for a purchase of $9.56 with a $10 bill, how much money should you receive in change? What will you do if the change that is given to you is one quarter, two dimes, and four pennies?

Four $1 bills  $4.00 One quarter 

0.25



0.05

One penny



0.01

Total

 $4.31

One nickel

To find out if this is the correct amount, we subtract the amount of the bill from $20.00.

$20.00  15.64 $ 4.36

The change was not correct. It is off by 5 cents. Instead of the nickel, I should have been given a dime.

Answers 4. a. 4.65 b. 4.6437 5. 4.677 6. $0.44; Tell the clerk that you have been given too much change. Instead of two dimes, you should have received one dime and one nickel.

216

Chapter 3 Decimals

7. Find the perimeter of each stamp in Example 7 from the dimensions given below. a. Each side is 1.38 inches

EXAMPLE 7

Find the perimeter of each of the following stamps. Write

your answer as a decimal, rounded to the nearest tenth, if necessary.

a.

Each side is 3.5 centimeters

b.

b. Base  6.6 centimeters,

Base  2.625 inches

other two sides  4.7 centimeters

Other two sides  1.875 inches

SOLUTION

To find the perimeter, we add the lengths of all the sides together.

a. P  3.5  3.5  3.5  3.5  14.0 cm b. P  2.625  1.875  1.875  6.4 in.

STUDY SKILLS Begin to Develop Confidence with Word Problems The main difference between people who are good at working word problems and those who are not seems to be confidence. People with confidence know that no matter how long it takes them, they will eventually be able to solve the problem they are working on. Those without confidence begin by saying to themselves, “I’ll never be able to work this problem.” If you are in this second group, then instead of telling yourself that you can’t do word problems, that you don’t like them, or that they’re not good for anything anyway, decide to do whatever it takes to master them.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. When adding numbers with decimals, why is it important to line up the decimal points? 2. Write 379.6 in mixed-number notation. 3. Look at Example 6 in this section of your book. If I had given the person at the cash register a $20 bill and four pennies, how much change should I then have received? 4. How many quarters does the decimal 0.75 represent?

Answers 7. a. 5.52 in. b. 16.0 cm

3.2 Problem Set

217

Problem Set 3.2 A Find each of the following sums. (Add.) [Examples 1, 3] 1. 2.91  3.28

2. 8.97  2.04

3. 0.04  0.31  0.78

4. 0.06  0.92  0.65

5. 3.89  2.4

6. 7.65  3.8

7. 4.532  1.81  2.7

8. 9.679  3.49  6.5

9. 0.081  5  2.94

13. 7.123

10. 0.396  7  3.96

11. 5.0003  6.78  0.004

12. 27.0179  7.89  0.009

14. 5.432

15. 9.001

16. 6.003

8.12

4.32

8.01

5.02

9.1

3.2

7.1

4.1

19. 543.21

20. 987.654

123.45

456.789

17. 89.7854

18.

57.4698

3.4

9.89

65.35

32.032

100.006

572.0079

A Find each of the following differences. (Subtract.) [Examples 2, 4] 21. 99.34  88.23

22. 47.69  36.58

23. 5.97  2.4

24. 9.87  1.04

25. 6.3  2.08

26. 7.5  3.04

27. 149.37  28.96

28. 796.45  32.68

29. 45  0.067

30. 48  0.075

31. 8  0.327

32. 12  0.962

33. 765.432  234.567

34. 654.321  123.456

218

Chapter 3 Decimals

A Subtract. [Example 4] 35.

36.

34.07  6.18

37.

25.008  3.119

40.04  4.4

38.

39.

50.05  5.5

768.436

40.

356.998

495.237  247.668

A Add and subtract as indicated. [Examples 1–5] 41. (7.8  4.3)  2.5

42. (8.3  1.2)  3.4

43. 7.8  (4.3  2.5)

44. 8.3  (1.2  3.4)

45. (9.7  5.2)  1.4

46. (7.8  3.2)  1.5

47. 9.7  (5.2  1.4)

48. 7.8  (3.2  1.5)

49. Subtract 5 from the sum of 8.2 and 0.072.

50. Subtract 8 from the sum of 9.37 and 2.5.

51. What number is added to 0.035 to obtain 4.036?

52. What number is added to 0.043 to obtain 6.054?

B

Applying the Concepts

[Examples 6, 7]

53. 100 Meters The chart shows the fastest times for the

54. Computers The chart shows how many computers can

women’s 100 meters in the Olympics. How much faster

be found in the countries containing the most comput-

was Christine Arron’s time than the first time recorded

ers. What is the total number of computers that can be

in 1928?

found in these three countries?

Who’s Connected?

Faster Than... Florence Griffith Joyner, 1988

10.49 sec

United States Marion Jones, 1998

240.5

10.65 sec

Christine Arron, 1998

10.73 sec

Merlene Ottey, 1996

10.74 sec

Japan

77.9 Millions of computers

Source: www.tenmojo.com

55. Take-Home Pay A college professor making $2,105.96

Germany

54.5

Source: Computer Industry Almanac Inc.

56. Take-Home Pay A cook making $1,504.75 a month has

per month has deducted from her check $311.93 for

deductions of $157.32 for federal income tax, $58.52

federal income tax, $158.21 for retirement, and $64.72

for Social Security, and $45.12 for state income tax.

for state income tax. How much does the professor

How much does the cook take home after the deduc-

take home after the deductions have been taken from

tions have been taken from his check?

her monthly income?

219

3.2 Problem Set 57. Perimeter of a Stamp

58. Perimeter of a Stamp

This

This

stamp was issued in 2001 to

Frida Kahlo. The stamp was is-

honor the Italian scientist

sued in 2001 and is the first

Enrico Fermi. The stamp

U.S. stamp to honor a Hispanic

caused some discussion be-

© 2004 Banco de México

stamp shows the Mexican artist

woman. The image area of the stamp has a width of 0.84 inches and a length of 1.41 inches. Find the perimeter of the image.

cause some of the mathematics in the upper left corner of the stamp is incorrect. The image area of the stamp has a width of 21.4 millimeters and a length of 35.8 millimeters. Find the perimeter of the image.

59. Change A person buys $4.57 worth of candy. If he pays

60. Checking Account A checking account contains $342.38.

for the candy with a $10 bill, how much change should

If checks are written for $25.04, $36.71, and $210, how

he receive?

much money is left in the account?

RECORD ALL CHARGES OR CREDITS THAT AFFECT YOUR ACCOUNT NUMBER

DATE

DESCRIPTION OF TRANSACTION

PAYMENT/DEBIT (-)

2/8 Deposit 1457 2/8 Woolworths 1458 2/9 Walgreens 1459 2/11 Electric Company

61. Sydney Olympics The chart show the top finishing times

$25 04 $36 71 $210 00

DEPOSIT/CREDIT (+)

$342 38

BALANCE

$342 38 ?

62. Sydney Olympics The chart shows the top finishing times

for the mens’ 400-meter freestyle swim during Sydney’s

for the women’s 400-meter race during the Sydney

Olympics. How much faster was Ian Thorpe than Emil-

Olympics. How much faster was Lorraine Graham than

iano Brembilla?

Katharine Merry?

400-meter Freestyle Swimming

Sydney Olympics

Final times for the 400-meter freestyle swim.

The chart shows the top finishing times for the women’s 400-meter race during the Sydney Olympics.

Ian Thorpe

3:40.59

Massimiliano Rosolino

3:43.40

Klete Keller

3:47.00

Emiliano Brembilla

3:47.01 Source: espn.com Source: espn.com

Cathy Freeman

49.11

Lorraine Graham

49.58

Katharine Merry

49.72

Donna Fraser

49.79

220

Chapter 3 Decimals

63. Geometry A rectangle has a perimeter of 9.5 inches. If

64. Geometry A rectangle has a perimeter of 11 inches. If

the length is 2.75 inches, find the width.

65. Change Suppose you eat dinner in a restaurant and the

the width is 2.5 inches, find the length.

66. Change Suppose you buy some tools at the hardware

bill comes to $16.76. If you give the cashier a $20 bill

store and the bill comes to $37.87. If you give the

and a penny, how much change should you receive?

cashier two $20 bills and 2 pennies, how much change

List the bills and coins you should receive for change.

should you receive? List the bills and coins you should receive for change.

Sequences Find the next number in each sequence. 67. 2.5, 2.75, 3, . . .

68. 3.125, 3.375, 3.625, . . .

Getting Ready for the Next Section To understand how to multiply decimals, we need to understand multiplication with whole numbers, fractions, and mixed numbers. The following problems review these concepts. 3 10

1 10

69.   

 10  3

73. 5 

5 10

3 10

5 10

6 10

70.   

7 10

74. 7  

5 100

3 1,000

3 100

17 100

7 100

31 100

71.   

72.   

75. 56  25

76. 39(48)

1 10

7 100

5 10

4 100

77.   

78.   

79. 2  

80. 3  

81. 305(436)

82. 403(522)

83. 5(420  3)

84. 3(550  2)

Maintaining Your Skills Use the rule for order of operations to simplify each expression.

85. 30  5  2

86. 60  3  10

87. 22  2  3

88. 37  7  2

89. 12  18  2  1

90. 15  10  5  4

91. 3  52  75  5  23

92. 2  32  18  3  24

Multiplication with Decimals; Circumference and Area of a Circle Introduction . . . The distance around a circle is called the circumference. If you know the circum-

3.3 Objectives A Multiply decimal numbers. B Solve application problems involving decimals.

ference of a bicycle wheel, and you ride the bicycle for one mile, you can calculate how many times the wheel has turned through one complete revolution. In

C

Find the circumference of a circle.

this section we learn how to multiply decimal numbers, and this gives us the information we need to work with circles and their circumferences.

Examples now playing at

MathTV.com/books

Trail: 1 mile

A Multiplying with Decimals Before we introduce circumference, we need to back up and discuss multiplication with decimals. Suppose that during a half-price sale a calendar that usually sells for $6.42 is priced at $3.21. Therefore it must be true that 1  of 6.42 is 3.21 2 1

But, because 2 can be written as 0.5 and of translates to multiply, we can write this problem again as 0.5  6.42  3.21 If we were to ignore the decimal points in this problem and simply multiply 5 and 642, the result would be 3,210. So, multiplication with decimal numbers is similar to multiplication with whole numbers. The difference lies in deciding where to place the decimal point in the answer. To find out how this is done, we can use fraction notation.

PRACTICE PROBLEMS

EXAMPLE 1

Change each decimal to a fraction and multiply:

0.5  0.3

SOLUTION

To indicate multiplication we are using a  sign here instead of a dot so we won’t confuse the decimal points with the multiplication symbol.

1. Change each decimal to a fraction and multiply. Write your answer as a decimal. a. 0.4  0.6 b. 0.04  0.06

Changing each decimal to a fraction and multiplying, we have 5 3 0.5  0.3     Change to fractions 10 10 15   100

Multiply numerators and multiply denominators

 0.15

Write the answer in decimal form

The result is 0.15, which has two digits to the right of the decimal point. What we want to do now is find a shortcut that will allow us to multiply decimals without first having to change each decimal number to a fraction. Let’s look

Answer 1. a. 0.24 b. 0.0024

at another example.

3.3 Multiplication with Decimals; Circumference and Area of a Circle

221

222

2. Change each decimal to a fraction and multiply. Write your answer as a decimal. a. 0.5  0.007 b. 0.05  0.07

Chapter 3 Decimals

EXAMPLE 2 SOLUTION

Change each decimal to a fraction and multiply: 0.05  0.003

5 3 0.05  0.003     100 1,000

Change to fractions

15   100,000

Multiply numerators and multiply denominators

 0.00015

Write the answer in decimal form

The result is 0.00015, which has a total of five digits to the right of the decimal point. Looking over these first two examples, we can see that the digits in the result are just what we would get if we simply forgot about the decimal points and multiplied; that is, 3  5  15. The decimal point in the result is placed so that the total number of digits to its right is the same as the total number of digits to the right of both decimal points in the original two numbers. The reason this is true becomes clear when we look at the denominators after we have changed from decimals to fractions.

3. Change to fractions and multiply: a. 3.5  0.04 b. 0.35  0.4

EXAMPLE 3 SOLUTION

Multiply: 2.1  0.07

7 1 2.1  0.07  2    10 100

Change to fractions

7 21     10 100 147   1,000

Multiply numerators and multiply denominators

 0.147

Write the answer as a decimal

Again, the digits in the answer come from multiplying 21  7  147. The decimal point is placed so that there are three digits to its right, because that is the total number of digits to the right of the decimal points in 2.1 and 0.07. We summarize this discussion with a rule.

Rule To multiply two decimal numbers:

1. Multiply as you would if the decimal points were not there. 2. Place the decimal point in the answer so that the number of digits to its right is equal to the total number of digits to the right of the decimal points in the original two numbers in the problem.

4. How many digits will be to the right of the decimal point in the following products? a. 3.706  55.88 b. 37.06  0.5588

EXAMPLE 4

2.987  24.82

SOLUTION Answers 2. Both are 0.0035 3. Both are 0.14 4. a. 5 b. 6

How many digits will be to the right of the decimal point in

the following product?

There are three digits to the right of the decimal point in 2.987 and

two digits to the right in 24.82. Therefore, there will be 3  2  5 digits to the right of the decimal point in their product.

223

3.3 Multiplication with Decimals; Circumference and Area of a Circle

EXAMPLE 5 SOLUTION

Multiply: 3.05  4.36

We can set this up as if it were a multiplication problem with whole

numbers. We multiply and then place the decimal point in the correct position in

5. Multiply. a. 4.03  5.22 b. 40.3  0.522

the answer. 3.05

m888 2 digits to the right of decimal point

 4.36

m888 2 digits to the right of decimal point

1830 915 12 20 13.2980 m888

The decimal point is placed so that there are 2  2  4 digits to its right

As you can see, multiplying decimal numbers is just like multiplying whole numbers, except that we must place the decimal point in the result in the correct position.

Estimating Look back to Example 5. We could have placed the decimal point in the answer by rounding the two numbers to the nearest whole number and then multiplying them. Because 3.05 rounds to 3 and 4.36 rounds to 4, and the product of 3 and 4 is 12, we estimate that the answer to 3.05  4.36 will be close to 12. We then place the decimal point in the product 132980 between the 3 and the 2 in order to make it into a number close to 12.

EXAMPLE 6

Estimate the answer to each of the following products.

a. 29.4  8.2 SOLUTION

b. 68.5  172 c. (6.32)2

a. Because 29.4 is approximately 30 and 8.2 is approximately 8, we estimate this product to be about 30  8  240. (If we were

6. Estimate the answer to each product. a. 82.3  5.8 b. 37.5  178 c. (8.21)2

to multiply 29.4 and 8.2, we would find the product to be exactly 241.08.)

b. Rounding 68.5 to 70 and 172 to 170, we estimate this product to be 70  170  11,900. (The exact answer is 11,782.) Note here that we do not always round the numbers to the nearest whole number when making estimates. The idea is to round to numbers that will be easy to multiply.

c. Because 6.32 is approximately 6 and 62  36, we estimate our answer to be close to 36. (The actual answer is 39.9424.)

Answers 5. Both are 21.0366 6. a. 480 b. 7,200 c. 64

224

Chapter 3 Decimals

Combined Operations We can use the rule for order of operations to simplify expressions involving decimal numbers and addition, subtraction, and multiplication.

7. Perform the indicated operations. a. 0.03(5.5  0.02) b. 0.03(0.55  0.002)

EXAMPLE 7 SOLUTION

Perform the indicated operations: 0.05(4.2  0.03)

We begin by adding inside the parentheses: 0.05(4.2  0.03)  0.05(4.23)

Add Multiply

 0.2115

Notice that we could also have used the distributive property first, and the result would be unchanged: 0.05(4.2  0.03)  0.05(4.2)  0.05(0.03)  0.210  0.0015  0.2115

8. Simplify. a. 5.7  14(2.4)2 b. 0.57  1.4(2.4)2

EXAMPLE 8 SOLUTION

Distributive property Multiply Add

Simplify: 4.8  12(3.2)2

According to the rule for order of operations, we must first evaluate

the number with an exponent, then multiply, and finally add. 4.8  12(3.2)2  4.8  12(10.24)  4.8  122.88  127.68

(3.2)2  10.24 Multiply Add

B Applications 9. Find the area of each stamp in

EXAMPLE 9

Example 11 from the dimensions given below. Round answers to the nearest hundredth. a. Each side is 1.38 inches

Find the area of each of the following stamps.

a.

Each side is 35.0 millimeters

b. Length  39.6 millimeters,

b. Round to the nearest hundredth. PEANUTS reprinted by permission of United Feature Syndicate, Inc.

width  25.1 millimeters

SOLUTION Answers 7. a. 0.1656 b. 0.01656 8. a. 86.34 b. 8.634 9. a. 1.90 in. b. 993.96 mm

Applying our formulas for area we have

a. A  s 2  (35 mm)2  1,225 mm2 b. A  lw  (1.56 in.)(0.99 in.)  1.54 in2

Length  1.56 inches Width  0.99 inches

225

3.3 Multiplication with Decimals; Circumference and Area of a Circle

EXAMPLE 10

Sally earns $6.82 for each of the first 36 hours she works

in one week and $10.23 in overtime pay for each additional hour she works in the same week. How much money will she make if she works 42 hours in one week?

SOLUTION

10. How much will Sally make if she works 50 hours in one week?

The difference between 42 and 36 is 6 hours of overtime pay. The

total amount of money she will make is

Note

Pay for the next 6 hours

{

{

Pay for the first 36 hours

6.82(36)  10.23(6)  245.52  61.38  306.90 She will make $306.90 for working 42 hours in one week.

To estimate the answer to Example 10 before doing the actual calculations, we would do the following: 6(40)  10(6)  240  60  300

C Circumference FACTS FROM GEOMETRY The Circumference of a Circle The circumference of a circle is the distance around the outside, just as the perimeter of a polygon is the distance around the outside. The circumference of a circle can be found by measuring its radius or diameter and then using the appropriate formula. The radius of a circle is the distance from the center of the circle to the circle itself. The radius is denoted by the letter r. The diameter of a circle is the distance from one side to the other, through the center. The diameter is denoted by the letter d. In Figure 1 we can see that the diameter is twice the radius, or d  2r The relationship between the circumference and the diameter or radius is not as obvious. As a matter of fact, it takes some fairly complicated mathematics to show just what the relationship between the circumference and the diameter is.

C r r d

C = circumference r = radius d = diameter

r

FIGURE 1 If you took a string and actually measured the circumference of a circle by wrapping the string around the circle and then measured the diameter of the same circle, you would find that the ratio of the circumference to the diameter, C/d, would be approximately equal to 3.14. The actual ratio of C to d in any circle is an irrational number. It can’t be written in decimal form. We use the symbol π (Greek pi) to represent this ratio. In symbols the relationship between the circumference and the diameter in any circle is C   π d Answer 10. $388.74

226

Chapter 3 Decimals

Knowing what we do about the relationship between division and multiplication, we can rewrite this formula as C  πd This is the formula for the circumference of a circle. When we do the actual calculations, we will use the approximation 3.14 for π. Because d  2r, the same formula written in terms of the radius is C  2πr

Here are some examples that show how we use the formulas given above to find the circumference of a circle.

11. Find the circumference of a circle with a diameter of 3 centimeters.

EXAMPLE 11

Find the circumference of a circle with a diameter of 5

feet.

SOLUTION

Substituting 5 for d in the formula C  πd, and using 3.14 for π, we

have C  3.14(5)  15.7 feet

12. Find the circumference for

EXAMPLE 12

each coin in Example 12 from the dimensions given below. Round answers to the nearest hundredth. a. Diameter  0.92 inches

Find the circumference of each coin.

a. 1 Euro coin (Round to the nearest whole number.)

Diameter  23.25 millimeters

b. Radius  13.20 millimeters

b. Susan B. Anthony dollar (Round to the nearest hundredth.)

Radius  0.52 inch

SOLUTION

Applying our formulas for circumference we have:

a. C  π d (3.14)(23.25) 73 mm b. C  2πr 2(3.14)(0.52) 3.27 in.

Answers 11. 9.42 cm 12. a. 2.89 in. b. 82.90 mm

227

3.3 Multiplication with Decimals; Circumference and Area of a Circle

FACTS FROM GEOMETRY Other Formulas Involving π Two figures are presented here, along with some important formulas that are associated with each figure. As you can see, each of the formulas contains the number π. When we do the actual calculations, we will use the approximation 3.14 for π.

h

r r Area  π(radius)2 A  πr 2

Volume  π(radius)2(height) V  πr 2h

FIGURE 2 Circle

FIGURE 3 Right circular cylinder

EXAMPLE 13 SOLUTION

Find the area of a circle with a diameter of 10 feet.

13. Find the area of a circle with a diameter of 20 feet.

The formula for the area of a circle is A  πr 2. Because the radius r is

half the diameter and the diameter is 10 feet, the radius is 5 feet. Therefore, A  πr 2  (3.14)(5)2  (3.14)(25)  78.5 ft2

EXAMPLE 14

The drinking straw shown in Figure 4 has a radius of 0.125

inch and a length of 6 inches. To the nearest thousandth, find the volume of liquid that it will hold.

14. Find the volume of the straw in Example 14, if the radius is doubled. Round your answer to the nearest thousandth.

0.125 in.

6 in.

FIGURE 4

SOLUTION

The total volume is found from the formula for the volume of a right

circular cylinder. In this case, the radius is r  0.125, and the height is h  6. We approximate π with 3.14. V  πr 2h  (3.14)(0.125)2(6)  (3.14)(0.015625)(6)  0.294 in3 to the nearest thousandth

Answers 13. 314 ft2 14. 1.178 in3

228

Chapter 3 Decimals

STUDY SKILLS Increase Effectiveness You want to become more and more effective with the time you spend on your homework. You want to increase the amount of learning you obtain in the time you have set aside. Increase those activities that you feel are the most beneficial and decrease those that have not given you the results you want.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. If you multiply 34.76 and 0.072, how many digits will be to the right of the decimal point in your answer? 2. To simplify the expression 0.053(9)  67.42, what would be the first step according to the rule for order of operations? 3. What is the purpose of estimating? 4. What are some applications of decimals that we use in our everyday lives?

229

3.3 Problem Set

Problem Set 3.3 A Find each of the following products. (Multiply.) [Examples 1–3, 5] 1.

0.7

2.

3.

0.8  0.3 

7. 2.6(0.3)

8. 8.9(0.2)

13.

19.

25.

4.003  6.07 

14.

0.1  0.02 

20.

49.94  1,000 

26.

0.07

4.

 0.4 

 0.4 

9.

0.9  0.88 

7.0001  3.04 

15. 5(0.006)

0.3  0.02 

21. 2.796(10)

157.02  10,000 

27.

987.654  10,000 

0.8

5.

10.

0.8  0.99 

16. 7(0.005)

22. 97.531(100)

28.

6.

0.03

 0.03 

 0.09 

11.

0.07  0.002 

3.12  0.005 

12.

4.69  0.006 

17. 75.14

18. 963.8

 2.5 

 0.24 

23. 0.0043

24. 12.345

 100 

 1,000 

1.23  100,000 

A Perform the following operations according to the rule for order of operations. [Examples 7, 8] 29. 2.1(3.5  2.6)

30. 5.4(9.9  6.6)

31. 0.05(0.02  0.03)

32. 0.04(0.07  0.09)

33. 2.02(0.03  2.5)

34. 4.04(0.05  6.6)

35. (2.1  0.03)(3.4  0.05)

36. (9.2  0.01)(3.5  0.03)

37. (2.1  0.1)(2.1  0.1)

38. (9.6  0.5)(9.6  0.5)

39. 3.08  0.2(5  0.03)

40. 4.09  0.5(6  0.02)

41. 4.23  5(0.04  0.09)

42. 7.89  2(0.31  0.76)

43. 2.5  10(4.3)2

44. 3.6  15(2.1)2

45. 100(1  0.08)2

46. 500(1  0.12)2

47. (1.5)2  (2.5)2  (3.5)2

48. (1.1)2  (2.1)2  (3.1)2

230

B

Chapter 3 Decimals

Applying the Concepts

[Examples 9–14]

Solve each of the following word problems. Note that not all of the problems are solved by simply multiplying the numbers in the problems. Many of the problems involve addition and subtraction as well as multiplication.

49. Google Earth This Google Earth image shows an aerial

50. Google Earth This is a 3D model of the Louvre Museum

view of a crop circle found near Wroughton, England. If

in Paris, France. The pyramid that dominates the

the crop circle has a radius of 59.13 meters, what is its

Napoleon Courtyard has a height of 21.65 meters and a

circumference? Use the approximation 3.14 for π.

square base with sides of 35.50 meters. What is the

Round to the nearest hundredth.

volume of the pyramid to the nearest whole number? Hint: The volume of a pyramid can be found by the equation V  3(area of the base)(height). 1

51. Number Problem What is the product of 6 and the sum of 0.001 and 0.02?

53. Number Problem What does multiplying a decimal number by 100 do to the decimal point?

55. Home Mortgage On a certain home mortgage, there is a

52. Number Problem Find the product of 8 and the sum of 0.03 and 0.002.

54. Number Problem What does multiplying a decimal number by 1,000 do to the decimal point?

56. Caffeine Content If 1 cup of regular coffee contains 105

monthly payment of $9.66 for every $1,000 that is bor-

milligrams of caffeine, how much caffeine is contained

rowed. What is the monthly payment on this type of

in 3.5 cups of coffee?

loan if $143,000 is borrowed?

57. Geometry of a Coin The $1 coin shown here depicts

58. Geometry of a Coin The Susan B. Anthony dollar shown

Sacagawea and her infant son. The diameter of the

here has a radius of 0.52 inches and a thickness of

coin is 26.5 mm, and the thickness is 2.00 mm. Find the

0.0079 inches. Find the following, rounding your an-

following, rounding your answers to the nearest hun-

swers to the nearest ten thousandth, if necessary. Use

dredth. Use 3.14 for π.

3.14 for π.

a. The circumference of the coin.

a. The circumference of the coin.

b. The area of one face of the coin.

b. The area of one face of the coin.

c. The volume of the coin.

c. The volume of the coin.

3.3 Problem Set

231

60. Area of a Stamp This stamp was

59. Area of a Stamp This stamp

issued in 2001 to honor the Italian

Kahlo. The image area of the

scientist Enrico Fermi. The image

stamp has a width of 0.84 inches

area of the stamp has a width of

and a length of 1.41 inches. Find the area of the image. Round to the nearest hundredth.

© 2004 Banco de México

shows the Mexican artist Frida

21.4 millimeters and a length of 35.8 millimeters. Find the area of the image. Round to the nearest whole number.

C Circumference Find the circumference and the area of each circle. Use 3.14 for π. [Examples 11–14] 61.

62.

2 in.

4 in.

63. Circumference The radius of the earth is approximately

64. Circumference The radius of the moon is approximately

3,900 miles. Find the circumference of the earth at the

1,100 miles. Find the circumference of the moon

equator. (The equator is a circle around the earth that

around its equator.

divides the earth into two equal halves.)

65. Bicycle Wheel The wheel on a 26-inch bicycle is such

66. Model Plane A model plane is flying in a circle with a

that the distance from the center of the wheel to the

radius of 40 feet. To the nearest foot, how far does it fly

outside of the tire is 26.75 inches. If you walk the bicy-

in one complete trip around the circle?

cle so that the wheel turns through one complete revolution, how many inches did you walk? Round to the nearest inch.

Find the volume of each right circular cylinder.

67.

68.

69.

70.

4 ft 8 ft 2 ft

8 ft 4 ft

2 ft

4 ft 4 ft

232

Chapter 3 Decimals

Getting Ready for the Next Section To get ready for the next section, which covers division with decimals, we will review division with whole numbers and fractions. Perform each of the following divisions. (Find the quotients.)

71. 3,758  2

72. 9,900  22

73. 50,032  33

74. 90,902  5

75. 205 ,9 6 0 

76. 304 ,6 2 0 

77. 4  8.7

78. 5  6.7

79. 27  1.848

80. 35  32.54

81. 383 1 ,3 5 0 

82. 253 7 7 ,8 0 0 

Maintaining Your Skills 83. Write the fractions in order from smallest to largest. 2  5

4  5

3  10

1  2

85. Write the numbers in order from smallest to largest. 5 1 6

3  2

2 1 3

25  12

84. Write the fractions in order from smallest to largest. 4  5

1  4

1  10

17  100

86. Write the numbers in order from smallest to largest. 11 1 12

19  12

4  3

1 1 6

Extending the Concepts 87. Containment System Holding tanks for hazardous liquids are often surrounded by containment tanks that will hold the hazardous liquid if the main tank begins to

16 ft

leak. We see that the center tank has a height of 16 feet and a radius of 6 feet. The

6 ft

outside containment tank has a height of 4 feet and a radius of 8 feet. If the center tank is full of heating fuel and develops a leak at the bottom, will the containment tank be able to hold all the heating fuel that leaks out?

4 ft

8 ft

Division with Decimals Introduction . . . The chart shows the top finishing times for the men’s 400-meter freestyle swim during Sydney’s Olympics. An Olympic pool is 50 meters long, so each swimmer

3.4 Objectives A Divide decimal numbers. B Solve application problems involving decimals.

will have to complete 8 lengths during a 400-meter race.

Examples now playing at

400-meter Freestyle Swimming

MathTV.com/books

Final times for the 400-meter freestyle swim

Ian Thorpe

3:40.59

Massimiliano Rosolino

3:43.40

Klete Keller

3:47.00

Emiliano Brembilla

3:47.01 Source: espn.com

During the race, each swimmer keeps track of how long it takes him to complete each length. To find the time of a swimmer’s average lap, we need to be able to divide with decimal numbers, which we will learn in this section.

A Dividing with Decimals PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

1. Divide: 4,626  30

Divide: 5,974  20 298

Note

,9 7 4  205

We can estimate the answer to Example 1 by rounding 5,974 to 6,000 and dividing by 20:

40 1 97 1 80

6,000  300 20

174



160 14 14

In the past we have written this answer as 298 2 or, after reducing the fraction, 0

7 . 298 1 0

Because

7  10

can be written as 0.7, we could also write our answer as 298.7.

This last form of our answer is exactly the same result we obtain if we write 5,974 as 5,974.0 and continue the division until we have no remainder. Here is how it looks: 298.7 m88 m8888888888 m888888888888888888

,9 7 4 .0  205 40

1 97

Notice that we place the decimal point in the answer directly above the decimal point in the problem

1 80

Note

We never need to make a mistake with division, because we can always check our results with multiplication.

174 160

14 0 14 0 0 Let’s try another division problem. This time one of the numbers in the problem will be a decimal.

3.4 Division with Decimals

Answer 1. 154.2

233

234

2. Divide. a. 33.5  5 b. 34.5  5 c. 35.5  5

Chapter 3 Decimals

EXAMPLE 2 SOLUTION

Divide: 34.8  4

We can use the ideas from Example 1 and divide as usual. The deci-

mal point in the answer will be placed directly above the decimal point in the problem. 8.7

Check:

8.7 

m88

4 .8  43 32

4

34.8

28 28 0 The answer is 8.7. We can use these facts to write a rule for dividing decimal numbers.

Rule To divide a decimal by a whole number, we do the usual long division as if there were no decimal point involved. The decimal point in the answer is placed directly above the decimal point in the problem.

Here are some more examples to illustrate the procedure. 3. Divide. a. 47.448  18 b. 474.48  18

EXAMPLE 3 SOLUTION

Divide: 49.896  27 1.848

9 .8 9 6  274 m88 m8888888888 m88888888888888888

Check this result by multiplication:

27

22 8

1.848 

21 6

27

1 29

12 936

1 08

36 96

216

49.896

216 0 We can write as many zeros as we choose after the rightmost digit in a decimal number without changing the value of the number. For example, 6.91  6.910  6.9100  6.91000 There are times when this can be very useful, as Example 4 shows. 4. Divide. a. 1,138.5  25 b. 113.85  25

EXAMPLE 4 SOLUTION

Divide: 1,138.9  35 32.54

,1 3 8 .9 0  351

18 9

Check:

m88 m8888888888 m88888888888888888

70

Write 0 after the 9. It doesn’t change the original number, but it gives us another digit to bring down.

1 05

88

17 5 Answers 2. a. 6.7 b. 6.9 c. 7.1 3. a. 2.636 b. 26.36 4. a. 45.54 b. 4.554

1 40 1 40 0

32.54 

35 162 70 976 2

1,138.90

235

3.4 Division with Decimals Until now we have considered only division by whole numbers. Extending division to include division by decimal numbers is a matter of knowing what to do about the decimal point in the divisor.

EXAMPLE 5 SOLUTION

Divide: 31.35  3.8

In fraction form, this problem is equivalent to

5. Divide. a. 13.23  4.2 b. 13.23  0.42

31.35  3.8 If we want to write the divisor as a whole number, we can multiply the numerator and the denominator of this fraction by 10: 31.35  10 313.5    38 3.8  10 So, since this fraction is equivalent to the original fraction, our original division problem is equivalent to 8.25

Put 0 after the last digit

m88 m888888888

1 3 .5 0  383 304

95

76

1 90 1 90 0

Note

We do not always use the rules for rounding numbers to make estimates. For example, to estimate the answer to Example 5, 31.35  3.8, we can get a rough estimate of the answer by reasoning that 3.8 is close to 4 and 31.35 is close to 32. Therefore, our answer will be approximately 32  4  8.

We can summarize division with decimal numbers by listing the following points, as illustrated by the first five examples.

Summary of Division with Decimals 1. We divide decimal numbers by the same process used in Chapter 1 to divide whole numbers. The decimal point in the answer is placed directly above the decimal point in the dividend.

2. We are free to write as many zeros after the last digit in a decimal number as we need.

3. If the divisor is a decimal, we can change it to a whole number by moving the decimal point to the right as many places as necessary so long as we move the decimal point in the dividend the same number of places. 6. Divide, and round your answer

EXAMPLE 6

Divide, and round the answer to the nearest hundredth:

0.3778  0.25

SOLUTION

First, we move the decimal point two places to the right: 0.25..3 7 .7 8 

to the nearest hundredth: 0.4553  0.32

Note

Moving the decimal point two places in both the divisor and the dividend is justified like this: 0.3778  100 37.78    0.25  100 25

Answers 5. a. 3.15 b. 31.5

236

Chapter 3 Decimals Then we divide, using long division: 1.5112 m88 m888888888 m88888888888888888 m8888888888888888888888888

7 .7 8 0 0  253 25

12 7 12 5

28 25

30 25

50 50 0 Rounding to the nearest hundredth, we have 1.51. We actually did not need to have this many digits to round to the hundredths column. We could have stopped at the thousandths column and rounded off.

7. Divide, and round to the nearest tenth. a. 19  0.06 b. 1.9  0.06

EXAMPLE 7 SOLUTION

Divide, and round to the nearest tenth: 17  0.03

Because we are rounding to the nearest tenth, we will continue di-

viding until we have a digit in the hundredths column. We don’t have to go any further to round to the tenths column. 5 66.66 7 .0 0 .0 0  0.03.1 m8 m888888888 m88888888888888888 m8888888888888888888888888

15

20 18

20 18

20 18

20 18 2 Rounding to the nearest tenth, we have 566.7.

B Applications 8. A woman earning $6.54 an hour receives a paycheck for $186.39. How many hours did the woman work?

EXAMPLE 8

If a man earning $7.26 an hour receives a paycheck for

$235.95, how many hours did he work?

SOLUTION

To find the number of hours the man worked, we divide $235.95 by

$7.26. 32.5

m8 m88888888

 3 55 .9.0  7.26.2 217 8

18 15 14 52

3 63 0 Answers 6. 1.42 7. a. 316.7 b. 31.7 8. 28.5 hours

3 63 0 0 The man worked 32.5 hours.

237

3.4 Division with Decimals

EXAMPLE 9

A telephone company charges $0.43 for the first minute

and then $0.33 for each additional minute for a long-distance call. If a longdistance call costs $3.07, how many minutes was the call?

SOLUTION

9. If the phone company in Example 9 charged $4.39 for a call, how long was the call?

To solve this problem we need to find the number of additional min-

utes for the call. To do so, we first subtract the cost of the first minute from the total cost, and then we divide the result by the cost of each additional minute. Without showing the actual arithmetic involved, the solution looks like this:

The number of

2.64 3.07  0.43      8 0.33 0.33 m8

additional minutes

Cost of the first minute m8

m8

Total cost of the call

Cost of each additional minute The call was 9 minutes long. (The number 8 is the number of additional minutes past the first minute.)

DESCRIPTIVE STATISTICS Grade Point Average I have always been surprised by the number of my students who have difficulty calculating their grade point average (GPA). During her first semester in college, my daughter, Amy, earned the following grades: Class

Units

Grade

Algebra Chemistry English History

5 4 3 3

B C A B

When her grades arrived in the mail, she told me she had a 3.0 grade point average, because the A and C grades averaged to a B. I told her that her GPA was a little less than a 3.0. What do you think? Can you calculate her GPA? If not, you will be able to after you finish this section. When you calculate your grade point average (GPA), you are calculating what is called a weighted average. To calculate your grade point average, you must first calculate the number of grade points you have earned in each class that you have completed. The number of grade points for a class is the product of the number of units the class is worth times the value of the grade received. The table below shows the value that is assigned to each grade. Grade

Value

A B C D F

4 3 2 1 0

If you earn a B in a 4-unit class, you earn 4  3  12 grade points. A grade of C in the same class gives you 4  2  8 grade points. To find your grade point average for one term (a semester or quarter), you must add your grade points and divide that total by the number of units. Round your answer to the nearest hundredth.

Answer 9. 13 minutes

238

10. If Amy had earned a B in chemistry, instead of a C, what grade point average would she have?

Chapter 3 Decimals

EXAMPLE 10

Calculate Amy’s grade point average using the informa-

tion above.

SOLUTION

We begin by writing in two more columns, one for the value of each

grade (4 for an A, 3 for a B, 2 for a C, 1 for a D, and 0 for an F), and another for the grade points earned for each class. To fill in the grade points column, we multiply the number of units by the value of the grade: Class Algebra Chemistry English History Total Units

Units

Grade

Value

5 4 3 3 15

B C A B

3 2 4 3

Grade Points 5  3  15 42 8 3  4  12 33 9 Total Grade Points: 44

To find her grade point average, we divide 44 by 15 and round (if necessary) to the nearest hundredth: 44 Grade point average    2.93 15

STUDY SKILLS Pay Attention to Instructions Taking a test is not like doing homework. On a test, the problems will be varied. When you do your homework, you usually work a number of similar problems. I have some students who do very well on their homework but become confused when they see the same problems on a test. The reason for their confusion is that they have not paid attention to the instructions on their homework. If a test problem asks for the mean of some numbers, then you must know the definition of the word mean. Likewise, if a test problem asks you to find a sum and then to round your answer to the nearest hundred, then you must know that the word sum indicates addition, and after you have added, you must round your answer as indicated.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 14 1. The answer to the division problem in Example 1 is 298 . Write this 20 number in decimal notation. 2. In Example 4 we place a 0 at the end of a number without changing the value of the number. Why is the placement of this 0 helpful? 3. The expression 0.3778  0.25 is equivalent to the expression 37.78  25 because each number was multiplied by what? 4. Round 372.1675 to the nearest tenth.

Answer 10. 3.20

3.4 Problem Set

Problem Set 3.4 A Perform each of the following divisions. [Examples 1–5] 1. 394  20

2. 486  30

3. 248  40

4. 372  80

5. 52 6 

6. 83 6 

7. 252 7 6 

8. 502 7 6 

9. 28.8  6

13. 359 2 .0 5 

10. 15.5  5

11. 77.6  8

12. 31.48  4

14. 261 4 6 .3 8 

15. 451 9 0 .8 

16. 553 4 2 .1 

239

240

Chapter 3 Decimals

17. 86.7  34

18. 411.4  44

19. 29.7  22

20. 488.4  88

21. 4.52 9 .2 5 

22. 3.32 1 .9 7 8 

23. 0.111 .0 8 9 

24. 0.752 .4 0 

25. 2.30 .1 1 5 

26. 6.60 .1 9 8 

27. 0.0121 .0 6 8 

28. 0.0520 .2 3 7 1 2 

29. 1.12 .4 2 

30. 2.27 .2 6 

3.4 Problem Set

241

Carry out each of the following divisions only so far as needed to round the results to the nearest hundredth. [Examples 6, 7] 5  31. 263

32. 184 7 

33. 3.35 6 

34. 4.47 5 

35. 0.1234  0.5

36. 0.543  2.1

37. 19  7

38. 16  6

.6 9  39. 0.0590

40. 0.0480 .4 9 

41. 1.99  0.5

42. 0.99  0.5

43. 2.99  0.5

44. 3.99  0.5

242

Chapter 3 Decimals

Calculator Problems

Work each of the following problems on your calculator. If rounding is necessary, round to the near-

est hundred thousandth.

45. 7  9

46. 11  13

49. 0.0503  0.0709

50. 429.87  16.925

B

Applying the Concepts

47. 243  0.791

48. 67.8  37.92

[Examples 8–10]

51. Google Earth The Google Earth map shows Yellowstone

52. Google Earth The Google Earth image shows a corn

National Park. There is an average of 2.3 moose per

field. A farmer harvests 29,952 bushels of corn. If the

square mile. If there are about 7,986 moose in Yellow-

farmer harvested 130 bushels per acre, how many

stone, how many square miles does Yellowstone

acres does the field cover?

cover? Round to the nearest square mile.

53. Hot Air Balloon Since the pilot of a hot air balloon can

54. Hot Air Balloon December and January are the best

only control the balloon’s altitude, he relies on the

times for traveling in a hot-air balloon because the jet

winds for travel. To ride on the jet streams, a hot air

streams in the Northern Hemisphere are the strongest.

balloon must rise as high as 12 kilometers. Convert this

They reach speeds of 400 kilometers per hour. Convert

to miles by dividing by 1.61. Round your answer to the

this to miles per hour by dividing by 1.61. Round to the

nearest tenth of a mile.

nearest whole number.

55. Wages If a woman earns $39.90 for working 6 hours, how much does she earn per hour?

56. Wages How many hours does a person making $6.78 per hour have to work in order to earn $257.64?

57. Gas Mileage If a car travels 336 miles on 15 gallons of

58. Gas Mileage If a car travels 392 miles on 16 gallons of

gas, how far will the car travel on 1 gallon of gas?

gas, how far will the car travel on 1 gallon of gas?

243

3.4 Problem Set

60. Wages Suppose a woman makes $286.08 in one week.

59. Wages Suppose a woman earns $6.78 an hour for the first 36 hours she works in a week and then $10.17 an

If she is paid $5.96 an hour for the first 36 hours she

hour in overtime pay for each additional hour she

works and then $8.94 an hour in overtime pay for each

works in the same week. If she makes $294.93 in one

additional hour she works in the same week, how

week, how many hours did she work overtime?

many hours did she work overtime that week?

61. Phone Bill Suppose a telephone company charges $0.41

62. Phone Bill Suppose a telephone company charges $0.45

for the first minute and then $0.32 for each additional

for the first three minutes and then $0.29 for each addi-

minute for a long-distance call. If a long-distance call

tional minute for a long-distance call. If a long-distance

costs $2.33, how many minutes was the call?

call costs $2.77, how many minutes was the call?

63. Women’s Golf The table gives the top five money earners for the Ladies’ Profes-

Rank

Name

Number of Events

Total Earnings

Average per Event

sional Golf Association (LPGA) in 2008, through June 1. Fill in the last column of

1.

Lorena Ochoa

25

$1,838,616

the table by finding the average earn-

2.

Annika Sorenstam

13

$1,295,585

ings per event for each golfer. Round

3.

Paula Creamer

24

$891,804

your answers to the nearest dollar.

4.

Seon Hwa Lee

28

$656,313

5.

Jeong Jang

27

$642,320

64. Men’s Golf The table gives the top five money earners for the men’s Profes-

Rank

sional Golf Association (PGA) in 2008, through June 1. Fill in the last column of the table by finding the average earnings per event for each golfer. Round your answers to the nearest dollar.

Name

Number of Events

Total Earnings

1.

Tiger Woods

5

$4,425,000

2.

Phil Mickelson

13

$3,872,270

3.

Geoff Ogilvy

13

$2,584,685

4.

Stewart Cink

13

$2,516,512

5.

Kenny Perry

15

$2,437,655

Grade Point Average The following grades were earned by Steve during his first term in college. Use these data to answer Problems 65–68.

65. Calculate Steve’s GPA.

Average per Event

Class

Units

Grade

Basic mathematics Health History English Chemistry

3 2 3 3 4

A B B C C

66. If his grade in chemistry had been a B instead of a C, by how much would his GPA have increased?

67. If his grade in health had been a C instead of a B, by how much would his grade point average have dropped?

68. If his grades in both English and chemistry had been B’s, what would his GPA have been?

244

Chapter 3 Decimals

Getting Ready for the Next Section In the next section we will consider the relationship between fractions and decimals in more detail. The problems below review some of the material that is necessary to make a successful start in the next section. Reduce to lowest terms. 220 1,000

71.  18

220 1,000

75. 

69. 

75 100

70. 

75 100

74. 

73. 

15 30

12

72. 

75 1,000

38 100

76. 

Write each fraction as an equivalent fraction with denominator 10. 1 2

3 5

77. 

78. 

Write each fraction as an equivalent fraction with denominator 100. 17 20

3 5

79. 

80. 

Write each fraction as an equivalent fraction with denominator 15. 4 5

4 1

2 3

81. 

82. 

83. 

2 1

6 5

84. 

7 3

85. 

86. 

Divide.

87. 3  4

88. 3  5

89. 7  8

90. 3  8

Maintaining Your Skills Simplify. 2

3

3 5



91. 15   

4

5

1 3



92. 15   

1

2

1 4



93. 4   

1

3

1 2

94. 6   



Fractions and Decimals, and the Volume of a Sphere Introduction . . . 1

If you are shopping for clothes and a store has a sale advertising 3 off the regular price, how much can you expect to pay for a pair of pants that normally sells for $31.95? If the sale price of the pants is $22.30, have they really been marked 1

down by 3? To answer questions like these, we need to know how to solve problems that involve fractions and decimals together.

3.5 Objectives A Convert fractions to decimals. B Convert decimals to fractions. C Simplify expressions containing fractions and decimals.

D

Solve applications involving fractions and decimals.

We begin this section by showing how to convert back and forth between fractions and decimals.

A Converting Fractions to Decimals

Examples now playing at

MathTV.com/books

You may recall that the notation we use for fractions can be interpreted as imply3

ing division. That is, the fraction 4 can be thought of as meaning “3 divided by 4.” We can use this idea to convert fractions to decimals.

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

3 Write  as a decimal. 4 Dividing 3 by 4, we have .75 m88

.0 0  43 28

1. Write as a decimal. 2 5 3 b.  5 4 c.  5

a. 

20 20 0 3 The fraction  is equal to the decimal 0.75. 4

EXAMPLE 2 SOLUTION

7 Write  as a decimal correct to the thousandths column. 12 Because we want the decimal to be rounded to the thousandths col-

umn, we divide to the ten thousandths column and round off to the thousandths column:

2. Write as a decimal correct to the thousandths column. 11 a.  12 12 b.  13

.5833 m88 m8888888888 m888888888888888888

.0 0 0 0  127 60

1 00 96

40 36

40 36 4 7 Rounding off to the thousandths column, we have 0.583. Because  is not ex12 actly the same as 0.583, we write 7  0.583 12 where the symbol is read “is approximately.”

3.5 Fractions and Decimals, and the Volume of a Sphere

Answers 1. a. 0.4 b. 0.6 c. 0.8 2. a. 0.917 b. 0.923

245

246

Chapter 3 Decimals If we wrote more zeros after 7.0000 in Example 2, the pattern of 3’s would continue for as many places as we could want. When we get a sequence of digits that repeat like this, 0.58333 . . . , we can indicate the repetition by writing  0.583

5

3. Write  11 as a decimal.

The bar over the 3 indicates that the 3 repeats from there on

EXAMPLE 3 SOLUTION

3 Write  as a decimal. 11 Dividing 3 by 11, we have .272727 m88 m8888888888 m888888888888888888 m88888888888888888888888888 m8888888888888888888888888888888888

.0 0  00 0 0  113 22

80 77

30 22

80 77

30 22

80 77

Note

The bar over the 2 and the 7 in 0.27 is used to indicate that the pattern repeats itself indefinitely.

3 No matter how long we continue the division, the remainder will never be 0, and the pattern will continue. We write the decimal form of 0.2 7   0.272727 . . .

3  11

as 0.2 7 , where

The dots mean “and so on”

B Converting Decimals to Fractions To convert decimals to fractions, we take advantage of the place values we assigned to the digits to the right of the decimal point. 4. Write as a fraction in lowest terms. a. 0.48 b. 0.048

EXAMPLE 4 SOLUTION

Write 0.38 as a fraction in lowest terms.

0.38 is 38 hundredths, or 38 0.38   100 19   Divide the numerator and the denominator 50

by 2 to reduce to lowest terms 19

The decimal 0.38 is equal to the fraction 5 . 0 We could check our work here by converting by dividing 19 by 50. That is, .38 m88

9 .0 0  501 15 0

4 00 4 00 Answers 12 3. 0.4 5  4. a.  25

0 6 125

b. 

19  50

back to a decimal. We do this

247

3.5 Fractions and Decimals, and the Volume of a Sphere

EXAMPLE 5 SOLUTION

5. Convert 0.025 to a fraction.

Convert 0.075 to a fraction.

We have 75 thousandths, or 75 0.075   1,000 3   40

EXAMPLE 6 SOLUTION

Divide the numerator and the denominator by 25 to reduce to lowest terms

Write 15.6 as a mixed number.

6. Write 12.8 as a mixed number.

Converting 0.6 to a fraction, we have 6 3 0.6     10 5

Reduce to lowest terms

3 3 Since 0.6  , we have 15.6  15. 5 5

C Problems Containing Both Fractions and Decimals We continue this section by working some problems that involve both fractions and decimals.

EXAMPLE 7

19 Simplify: (1.32  0.48) 50 19 SOLUTION In Example 4, we found that 0.38  . Therefore we can rewrite 50 the problem as

14 25

7. Simplify: (2.43  0.27)

19  (1.32  0.48)  0.38(1.32  0.48) Convert all numbers to decimals 50  0.38(1.80)

Add: 1.32  0.48 Multiply: 0.38  1.80

 0.684

EXAMPLE 8 SOLUTION

1 Simplify:   (0.75) 2 We could do this problem one

1 4

 5  2

3

5

8. Simplify:   0.25 

of two different ways. First, we could

convert all fractions to decimals and then simplify:

 

2 1   (0.75)   0.5  0.75(0.4) 2 5  0.5  0.300

Convert to decimals Multiply: 0.75  0.4 Add

 0.8

3 Or, we could convert 0.75 to  and then simplify: 4 1 2 1 3 2   0.75       Convert decimals to fractions 2 5 2 4 5

 

 

3 1     2 10

2 3  Multiply:  5 4

5 3     10 10

The common denominator is 10

8   10

Add numerators

4   5

Reduce to lowest terms 8

4

The answers are equivalent. That is, 0.8  10  5. Either method can be used with problems of this type.

Answers 1 40

4 5

5.  6. 12  7. 1.512 2 5

8. , or 0.4

248

Chapter 3 Decimals

1

3

3

1

5

2

9. Simplify:  (5.4)   (2.5)

EXAMPLE 9 SOLUTION

 

 

1 3 1 2 Simplify:  (2.4)   (3.2) 2 4 This expression can be simplified without any conversions between

fractions and decimals. To begin, we evaluate all numbers that contain exponents. Then we multiply. After that, we add. 1

(3.2)  2  (2.4)   4  (3.2)  8 (2.4)   16 1

3

1

2

1

Evaluate exponents Multiply by 81 and 116 Add

 0.3  0.2  0.5

A Applications 10. A shirt that normally sells for 1

$35.50 is on sale for 4 off. What is the sale price of the shirt? (Round to the nearest cent.)

EXAMPLE 10

If a shirt that normally sells for $27.99 is on sale for

1  3

off,

what is the sale price of the shirt?

SOLUTION

To find out how much the shirt is marked down, we must find

27.99. That is, we multiply

1  3

1  3

of

and 27.99, which is the same as dividing 27.99 by 3.

1 27.99  (27.99)    9.33 3 3 The shirt is marked down $9.33. The sale price is the original price less the amount it is marked down: Sale price  27.99  9.33  18.66 The sale price is $18.66. We also could have solved this problem by simply multi2

1

plying the original price by 3, since, if the shirt is marked 3 off, then the sale price must be

2  3

of the original price. Multiplying by

2  3

is the same as dividing by 3 and

then multiplying by 2. The answer would be the same.

11. Find the area of the stamp in

EXAMPLE 11

Find the area of the stamp.

Example 11 if Base  6.6 centimeters, height  3.3 centimeters

Write your answer as a decimal, rounded to the nearest hundredth.

5 Base  2  inches 8 1 Height  1  inches 4

SOLUTION

We can work the problem using fractions and then convert the an-

swer to a decimal. 1 1 5 A   bh   2  2 2 8

1

1

21

5

105

    1.64 in  1 4   2   8 4 64

2

Or, we can convert the fractions to decimals and then work the problem. 1 1 A   bh   (2.625)(1.25) 1.64 in2 2 2 Answers 9. 0.3 10. $26.63 11. 10.89 cm2

249

3.5 Fractions and Decimals, and the Volume of a Sphere

FACTS FROM GEOMETRY The Volume of a Sphere Figure 1 shows a sphere and the formula for its volume. Because the formula contains both the fraction

4  3

and the number π, and we have been using 3.14

for π, we can think of the formula as containing both a fraction and a decimal.

r

4

Volume = 3 π(radius) 3 = 43 πr 3 FIGURE 1 Sphere

EXAMPLE 12

Figure 2 is composed of a right circular cylinder with half a

12. If the radius in Figure 2 is dou-

sphere on top. (A half-sphere is called a hemisphere.) To the nearest tenth, find

bled so that it becomes 10 inches instead of 5 inches, what is the new volume of the figure? Round your answer to the nearest tenth.

the total volume enclosed by the figure.

10 in.

5 in.

FIGURE 2

SOLUTION

The total volume is found by adding the volume of the cylinder to

the volume of the hemisphere. V  volume of cylinder  volume of hemisphere 1 4  πr 2h     πr 3 2 3 1 4  (3.14)(5)2(10)     (3.14)(5)3 2 3 1 4  (3.14)(25)(10)     (3.14)(125) 2 3 2  785   (392.5) 3

4 2 1 4 Multiply:        2 3 6 3

785  785   3

Multiply: 2(392.5)  785

785  261.7

Divide 785 by 3, and round to the nearest tenth

 1,046.7 in3

Answer 12. 5,233.3 in3

250

Chapter 3 Decimals

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. To convert fractions to decimals, do we multiply or divide the numerator by the denominator? 2. The decimal 0.13 is equivalent to what fraction? 3. Write 36 thousandths in decimal form and in fraction form. 84 4. Explain how to write the fraction   in lowest terms. 1,000

251

3.5 Problem Set

Problem Set 3.5 A Each circle below is divided into 8 equal parts. The number below each circle indicates what fraction of the circle is shaded. Convert each fraction to a decimal. [Examples 1–3]

1.

2.

3.

1 – 8

4.

3 – 8

7 – 8

5 – 8

A Complete the following tables by converting each fraction to a decimal. [Examples 1–3] 5. Fraction

1  4

2  4

4  4

3  4

6. Fraction

1  5

2  5

3  5

4  5

7.

5  5

Fraction

Decimal

Decimal

1  6

2  6

3  6

4  6

5  6

6  6

Decimal

A Convert each of the following fractions to a decimal. [Examples 1–3] 1 2

12 25

8. 

14 25

9. 

18 32

14 32

10. 

11. 

12. 

A Write each fraction as a decimal correct to the hundredths column. [Examples 1–3] 13. 

12 13

14. 

17 19

15. 

3 11

16. 

2 23

18. 

3 28

19. 

12 43

20. 

17. 

5 11

15 51

B Complete the following table by converting each decimal to a fraction. 21. Decimal 0.125 Fraction

22. 0.250

0.375

0.500

0.625

0.750

0.875

Decimal Fraction

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

252

Chapter 3 Decimals

B Write each decimal as a fraction in lowest terms. [Examples 4–6] 23. 0.15

24. 0.45

25. 0.08

26. 0.06

27. 0.375

28. 0.475

32. 8.04

33. 1.22

34. 2.11

B Write each decimal as a mixed number. [Examples 6] 29. 5.6

30. 8.4

31. 5.06

C Simplify each of the following as much as possible, and write all answers as decimals. [Examples 7–9] 1 2

1 2

5

2

5 8

4

1

3

48.

 5  (7.5)   4  (6.4) 1

2

3 5

1

2

1 8

3 8

42.  (0.7)   (0.7)

2

46.   0.45 

4

50. (0.75)2   (7)

1

45.   0.35 

44. 8  (0.03)

 3  (5.4)   2  (3.2)

38. 

41.  (0.3)   (0.3)

5

3

1

2 5

1 5

40. 6.7   (0.45)

43. 6  (0.02)

2.99 1  2

37. 

36.  (1.8  7.6)

39. 3.4   (0.76)

47.

1.99 1  2

3 4

35.  (2.3  2.5)

1

2

49. (0.25)2   (3)

7 8

4 3

4 1

2

253

3.5 Problem Set

D

Applying the Concepts

[Examples 10–12]

51. Commuting The map shows the average number of days

52. Pitchers The chart shows the active major league

spent commuting per year in the United States’ largest

pitchers with the most career strikeouts. To compute

cities. Change the data for Houston to a mixed number.

the number of strikeouts per nine-inning game, divide by the total innings pitched and then multiply by 9. If Pedro Martinez had pitched 2,783 innings, write his strikeouts per game as a mixed number.

Life in a Car New York City, NY 6.7 Chicago, IL 5.7 Philadelphia, PA 5.3

King of the Hill

Los Angeles, CA 4.9 Phoenix, AZ 4.3 Dallas, TX 4.4

Randy Johnson

Houston, TX 4.4

4,789

Rodger Clemens

San Diego, CA 3.9

Greg Maddux

Source: U.S. Census Bureau

Pedro Martinez

4,672 3,371 3,117

Source: www.mlb.com, November 2008

53. Price of Beef If each pound of beef costs $4.99, how 1

much does 3 4 pounds cost?

1

54. Price of Gasoline What does it cost to fill a 15 2-gallon gas tank if the gasoline is priced at 429.9¢ per gallon?

1

55. Sale Price A dress that costs $78.99 is on sale for 3 off. What is the sale price of the dress?

57. Perimeter of the Sierpinski Triangle The diagram below

56. Sale Price A suit that normally sells for $221 is on sale 1

for 4 off. What is the sale price of the suit?

58. Perimeter of the Sierpinski Triangle The diagram below

shows one stage of what is known as the Sierpinski tri-

shows another stage of the Sierpinski triangle. Each tri-

angle. Each triangle in the diagram has three equal

angle in the diagram has three equal sides. The largest

sides. The large triangle is made up of 4 smaller trian-

triangle is made up of a number of smaller triangles. If

gles. If each side of the large triangle is 2 inches, and

each side of the large triangle is 2 inches, and each side

each side of the smaller triangles is 1 inch, what is the

of the smallest triangles is 0.5 inch, what is the perime-

perimeter of the shaded region?

ter of the shaded region?

254

Chapter 3 Decimals

59. Average Gain in Stock Price The table below shows the amount of gain each day of one week in 2008 for the price of an Internet company specializing in distance learning for college students. Complete the table by converting each fraction to a decimal, rounding to the nearest hundredth if necessary.

CHANGE IN STOCK PRICE Date

Gain ($)

Monday, March 6, 2008

3  4

Tuesday, March 7, 2008

9  16

Wednesday, March 8, 2008

3  32

Thursday, March 9, 2008

7  32

Friday, March 10, 2008

1  16

As a Decimal ($) (To the Nearest hundredth)

60. Average Gain in Stock Price The table below shows the amount of gain each day of one week in 2008 for the stock price of an online bookstore. Complete the table by converting each fraction to a decimal, rounding to the nearest hundredth, if necessary. CHANGE IN STOCK PRICE Date

Gain

Monday, March 6, 2008

1  16

Tuesday, March 7, 2008

3 1 8

Wednesday, March 8, 2008

3  8

Thursday, March 9, 2008

As a Decimal ($) (To the Nearest Hundredth)

13 5 16 3  8

Friday, March 10, 2008

61. Nutrition If 1 ounce of ground beef contains 50.75 calories and 1 ounce of halibut contains 27.5 calories, what 1

is the difference in calories between a 4 2-ounce serving of ground beef and a

1 4 2-ounce

serving of halibut?

62. Nutrition If a 1-ounce serving of baked potato contains 48.3 calories and a 1-ounce serving of chicken contains 1

24.6 calories, how many calories are in a meal of 5 4 ounces of chicken and a

1 3 3-ounce

baked potato?

3.5 Problem Set

255

Taxi Ride Recently, the Texas Junior College Teachers Association annual conference was held in Austin. At that time a taxi 1

1

ride in Austin was $1.25 for the first 5 of a mile and $0.25 for each additional 5 of a mile. The charge for a taxi to wait is $12.00 per hour. Use this information for Problems 63 through 66.

63. If the distance from one of the convention hotels to the

64. If you were to tip the driver of the taxi in Problem 63

airport is 7.5 miles, how much will it cost to take a taxi

$1.50, how much would it cost to take a taxi from the

from that hotel to the airport?

hotel to the airport?

65. Suppose the distance from one of the hotels to one of

66. Suppose that the distance from a hotel to the airport is

the western dance clubs in Austin is 12.4 miles. If the

8.2 miles, and the ride takes 20 minutes. Is it more ex-

fare meter in the taxi gives the charge for that trip as

pensive to take a taxi to the airport or to just sit in the

$16.50, is the meter working correctly?

taxi?

Volume Find the volume of each sphere. Round to the nearest hundredth. Use 3.14 for π. [Example 12] 67.

68.

3m

2m

Volume Find the volume of each figure. Round to the nearest tenth. Use 3.14 for π. [Example 12]

Hemisphere

69.

70.

Hemisphere

6 ft

3 ft

3 ft

6 ft

Area Find the total area enclosed by each figure below. Use 3.14 for π. 71.

Half circle

72.

6m Half circle 4m

4 in. 2m 4 in.

256

Chapter 3 Decimals

Getting Ready for the Next Section The problems below review the material on exponents we have covered previously. Expand and simplify.

73.

1

 3 

4

74.

3

 4 

3

75.

5

 6 

2

76.

3

 5 

3

77. (0.5)2

78. (0.1)3

79. (1.2)2

80. (2.1)2

81. 32  42

82. 52  122

83. 62  82

84. 22  32

Maintaining Your Skills 85. Find the sum of 827 and 25.

86. Find the difference of 827 and 25.

87. Find the product of 827 and 25.

88. Find the quotient of 827 and 25.

Square Roots and the Pythagorean Theorem Introduction . . . Figure 1 shows the front view of the roof of a tool shed. How do we find the

3.6 Objectives A Find square roots of numbers. B Use decimals to approximate square roots.

length d of the diagonal part of the roof? (Imagine that you are drawing the plans for the shed. Since the shed hasn’t been built yet, you can’t just measure the diagonal, but you need to know how long it will be so you can buy the correct

C

Solve problems with the Pythagorean Theorem.

amount of material to build the shed.)

d

5 ft

d

Examples now playing at

MathTV.com/books 12 ft

12 ft FIGURE 1

There is a formula from geometry that gives the length d: 2   52 d  12

where  is called the square root symbol. If we simplify what is under the square root symbol, we have this:  25 d  144   169  The expression 169  stands for the number we square to get 169. Because 13  13  169, that number is 13. Therefore the length d in our original diagram is 13 feet.

A Square Roots Here is a more detailed discussion of square roots. In Chapter 1, we did some work with exponents. In particular, we spent some time finding squares of numbers. For example, we considered expressions like this: 52  5  5  25 72  7  7  49 x2  x  x We say that “the square of 5 is 25” and “the square of 7 is 49.” To square a number, we multiply it by itself. When we ask for the square root of a given number, we want to know what number we square in order to obtain the given number. We say that the square root of 49 is 7, because 7 is the number we square to get 49. Likewise, the square root of 25 is 5, because 52  25. The symbol we use to denote square root is , which is also called a radical sign. Here is the precise definition of square root.

Definition The square root of a positive number a, written a  , is the number we square to get a. In symbols: If

a   b then b 2  a.

Note

The square root we are describing here is actually the principal square root. There is another square root that is a negative number. We won’t see it in this book, but, if you go on to take an algebra course, you will see it there.

We list some common square roots in Table 1.

3.6 Square Roots and the Pythagorean Theorem

257

258

Chapter 3 Decimals

TABLE 1

Statement

In Words

0 0 1 1 2 4 3 9 4 16 5 25

The The The The The The

square square square square square square

root root root root root root

Reason

of of of of of of

0 is 0 1 is 1 4 is 2 9 is 3 16 is 4 25 is 5

Because Because Because Because Because Because

02  0 12  1 22  4 32  9 42  16 52  25

Numbers like 1, 9, and 25, whose square roots are whole numbers, are called perfect squares. To find the square root of a perfect square, we look for the whole number that is squared to get the perfect square. The following examples involve square roots of perfect squares.

PRACTICE PROBLEMS 1. Simplify: 425 

EXAMPLE 1 SOLUTION

 Simplify: 764

The expression 764  means 7 times 64 . To simplify this expres-

 as 8 and multiply: sion, we write 64 764   7  8  56 We know 64   8, because 82  64. 2. Simplify: 36   4 

EXAMPLE 2 SOLUTION

Simplify: 9   16 

We write 9  as 3 and 16  as 4. Then we add: 9   16 347

3. Simplify:

  100 36

EXAMPLE 3 SOLUTION get

25 . 81

Simplify:

  81 25

We are looking for the number we square (multiply times itself) to

We know that when we multiply two fractions, we multiply the numera-

tors and multiply the denominators. Because 5  5  25 and 9  9  81, the square 25

5

must be 9. root of 8 1    9 81 25

Simplify each expression as much as possible. 4. 1436 

6.

  121 64

 9  5

because

2

5 5 25    9 9 81

In Examples 4–6, we simplify each expression as much as possible.

EXAMPLE 4 EXAMPLE 5

5. 81   25 

5

EXAMPLE 6

Simplify: 1225   12  5  60

  36   10  6  4 Simplify: 100

Simplify:

   11 121 49

7

because

 11  7

2

7 7 49       11 11 121

B Approximating Square Roots Answers 3 1. 20 2. 8 3.  4. 84 8 11

5. 4 6. 

5

So far in this section we have been concerned only with square roots of perfect squares. The next question is, “What about square roots of numbers that are not , for example?” We know that perfect squares, like 7 4 2

and

9 3

259

3.6 Square Roots and the Pythagorean Theorem And because 7 is between 4 and 9, 7  should be between 4  and 9 . That is,  should be between 2 and 3. But what is it exactly? The answer is, we cannot 7 write it exactly in decimal or fraction form. Because of this, it is called an irrational number. We can approximate it with a decimal, but we can never write it . The exactly with a decimal. Table 2 gives some decimal approximations for 7 decimal approximations were obtained by using a calculator. We could continue the list to any accuracy we desired. However, we would never reach a number in decimal form whose square was exactly 7. TABLE 2

APPROXIMATIONS FOR THE SQUARE ROOT OF 7 Accurate to the Nearest

The Square Root of 7 is 7   2.6   2.65 7   2.646 7   2.6458 7

Tenth Hundredth Thousandth Ten thousandth

EXAMPLE 7

Check by Squaring (2.6)2  6.76 (2.65)2  7.0225 (2.646)2  7.001316 (2.6458)2  7.00025764

 Give a decimal approximation for the expression 512

that is accurate to the nearest ten thousandth.

SOLUTION

Let’s agree not to round to the nearest ten thousandth until we have

7. Give a decimal approximation  that is for the expression 514 accurate to the nearest ten thousandth.

 3.4641016. first done all the calculations. Using a calculator, we find 12 Therefore,  5(3.4641016) 512

 12 on calculator

 17.320508

Multiplication To the nearest ten thousandth

 17.3205

EXAMPLE 8 SOLUTION

Approximate 301   137  to the nearest hundredth.

8. Approximate 405   147  to the nearest hundredth.

Using a calculator to approximate the square roots, we have 301   137  17.349352  11.704700  29.054052

To the nearest hundredth, the answer is 29.05.

EXAMPLE 9 SOLUTION

Approximate

 to the nearest thousandth.  11 7

Because we are using calculators, we first change

7  11

to a decimal

9. Approximate

 to the near 12 7

est thousandth.

and then find the square root:  0.636 3636  0.7977240  11 7

To the nearest thousandth, the answer is 0.798.

C The Pythagorean Theorem FACTS FROM GEOMETRY Perimeter A right triangle is a triangle that contains a 90° (or right) angle. The longest side

c

a

in a right triangle is called the hypotenuse, and we use the letter c to denote it. The two shorter sides are denoted by the letters a and b. The Pythagorean theorem states that the hypotenuse is the square root of the sum of the squares of the two shorter sides. In symbols: 2   b 2 c  a

90° b Answers 7. 18.7083 8. 32.25 9. 0.764

260

Chapter 3 Decimals

EXAMPLE 10

10. Find the length of the a.

hypotenuse in each right triangle.

Find the length of the hypotenuse in each right triangle.

a.

b. c

c

5 ft

3m

c

5 in.

4m 7 in.

SOLUTION

5 ft b.

c

We apply the formula given above.

a.

b.

When a  3 and b  4:

When a  5 and b  7:

2   4 2 c  3

2   7 2 c  5

 25 49 

 9 6  1

12 cm

 74 

 25  c  5 meters

c 8.60 inches

16 cm In part a, the solution is a whole number, whereas in part b, we must use a calcu. lator to get 8.60 as an approximation to 74

EXAMPLE 11

A ladder is leaning against the top of a 6-foot wall. If the

bottom of the ladder is 8 feet from the wall, how long is the ladder? 11. A wire from the top of a 12-foot pole is fastened to the ground by a stake that is 5 feet from the bottom of the pole. What is the length of the wire?

SOLUTION

A picture of the situation is shown in Figure 2. We let c denote the

length of the ladder. Applying the Pythagorean theorem, we have

2 c  6   8 2

 36 64   100 

6 ft

c

90°

 10 feet The ladder is 10 feet long.

8 ft FIGURE 2

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Which number is larger, the square of 10 or the square root of 10? 2 Give a definition for the square root of a number. 3. What two numbers will the square root of 20 fall between? 4. What is the Pythagorean theorem?

Answers 10. a. approx. 7.07 ft b. 20 cm 11. 13 ft

3.6 Problem Set

Problem Set 3.6 A Find each of the following square roots without using a calculator. [Example 1] 1. 64 

2. 100 

3. 81 

4. 49 

5. 36 

6. 144 

7. 25 

8. 169 

A Simplify each of the following expressions without using a calculator. [Examples 1–6] 9. 325 

10. 949 

11. 664 

12. 11100 

13. 159 

14. 836 

15. 169 

16. 916 

17. 49   64 

18. 1   0 

19. 16   9 

20. 25   4 

21. 325   949 

22. 664   11100 

23. 159   916 

24. 749   24 

25.

  49 16

26.

  121 100

27.

  64 36

28.

Indicate whether each of the statements in Problems 29–32 is True or False.

29. 4   9   4  9 30.

31. 25   9  25   9 

    25 2  5 16

1  6

32. 100   36   100   36

  144 81

261

262

Chapter 3 Decimals

C Find the length of the hypotenuse in each right triangle. Round to the nearest hundredth, if necessary. [Examples 10, 11] 33.

34.

35.

c

c

6 in.

c

5 yd

5 ft

12 ft

8 in. 5 yd

36.

37.

38.

c

4 in.

c

6 ft

5 in. c

24 cm

6 ft

7 cm

40.

39.

c

1 km

8 km

c 9m

15 m

B

Calculator Problems

[Examples 7–9]

Use a calculator to work problems 41 through 60. Approximate each of the following square roots to the nearest ten thousandth.

41. 1.25 

42. 12.5 

43. 125 

44. 1250 

Approximate each of the following expressions to the nearest hundredth.

45. 23 

46. 32 

 3 3

50. 

49. 

 2 2

47. 55 

51.

 3 1

48. 53 

52.

 2 1

Approximate each of the following expressions to the nearest thousandth.

53. 12   75 

54. 18   50 

55. 87 

56. 68 

57. 23   53 

58. 32   52 

59. 73 

60. 82 

3.6 Problem Set

263

Applying the Concepts 61. Google Earth The Google Earth image shows a right

62. Google Earth The Google Earth image shows three cities

triangle between three cities in the Los Angeles area. If

in Colorado. If the distance between Denver and North

the distance between Pomona and Ontario is 5.7 miles,

Washington is 2.5 miles, and the distance between

and the distance between Ontario and Upland is 3.6

Edgewater and Denver is 4 miles, what is the distance

miles, what is the distance between Pomona and

between North Washington and Edgewater? Round to

Upland? Round to the nearest tenth of a mile.

the nearest tenth.

North Washington

Upland

2.5 miles 3.6 miles

Edgewater Pomona

5.7 miles

Denver

4 miles

Ontario

63. Geometry One end of a wire is attached to the top of a

64. Geometry Two children are trying to cross a stream.

24-foot pole; the other end of the wire is anchored to

They want to use a log that goes from one bank to the

the ground 18 feet from the bottom of the pole. If the

other. If the left bank is 5 feet higher than the right

pole makes an angle of 90° with the ground, find the

bank and the stream is 12 feet wide, how long must a

length of the wire.

log be to just barely reach?

24 ft 5 ft 12 ft

90° 18 ft

65. Geometry A ladder is leaning against the top of a 15-

66. Geometry A wire from the top of a 24-foot pole is fas-

foot wall. If the bottom of the ladder is 20 feet from the

tened to the ground by a stake that is 10 feet from the

wall, how long is the ladder?

bottom of the pole. How long is the wire?

67. Surveying A surveying team wants to calculate the

68. Surveying A surveying team wants to calculate the

length of a straight tunnel through a mountain. They

length of a straight tunnel through a mountain. They

form a right angle by connecting lines from each end of

form a right angle by connecting lines from each end of

the proposed tunnel. One of the connecting lines is 3

the proposed tunnel. One of the connecting lines is 6

miles, and the other is 4 miles. What is the length of the

miles, and the other is 8 miles. What is the length of the

proposed tunnel?

proposed tunnel?

264

Chapter 3 Decimals

Maintaining Your Skills Factor each of the following numbers into the product of two numbers, one of which is a perfect square. (Remember from Chapter 1, a perfect square is 1, 4, 9, 16, 25, 36, . . ., etc.)

69. 32

70. 200

71. 75

72. 12

73. 50

74. 20

75. 40

76. 18

77. 32

78. 27

79. 98

80. 72

81. 48

82. 121

The problems below review material involving fractions and mixed numbers. Perform the indicated operations. Write your answers as whole numbers, proper fractions, or mixed numbers. 5 7

14 25

1 4

83.   

2 10

5 10

1 8

3 10

2 100

86. 8   1 

1 10

3 10

84. 1   2 

85. 4   5 

9 10

3 10

1 5

7 10

1 10

97 100

87. 3   2 

88. 6   2 

89. 7   4 

90. 3   1 

3  8 91.  6  7

3  4 92.  1 1    2 4

2 3    3 5 93.  2 3    3 5

4 1    5 3 94.  4 1    5 3

Chapter 3 Summary Place Value [3.1] EXAMPLES The place values for the first five places to the right of the decimal point are

1. The number 4.123 in words is “four and one hundred twentythree thousandths.”

Decimal Point

.

Tenths 1  10

Hundredths

Thousandths

1  100

1  1,000

Ten Thousandths

Hundred Thousandths

1  10,000

1  100,000

Rounding Decimals [3.1] If the digit in the column to the right of the one we are rounding to is 5 or more,

2. 357.753 rounded to the nearest Tenth: 357.8 Ten: 360

we add 1 to the digit in the column we are rounding to; otherwise, we leave it alone. We then replace all digits to the right of the column we are rounding to with zeros if they are to the left of the decimal point; otherwise, we simply delete them.

Addition and Subtraction with Decimals [3.2] To add (or subtract) decimal numbers, we align the decimal points and add (or

3.

subtract) as if we were adding (or subtracting) whole numbers. The decimal point in the answer goes directly below the decimal points in the problem.

3.400 25.060  0.347 28.807

Multiplication with Decimals [3.3] To multiply two decimal numbers, we multiply as if the decimal points were not

4. If we multiply 3.49  5.863, there will be a total of 2  3  5 digits to the right of the decimal point in the answer.

there. The decimal point in the product has as many digits to the right as there are total digits to the right of the decimal points in the two original numbers.

Division with Decimals [3.4]

move the decimal point in the dividend the same number of places to the right. Once the divisor is a whole number, we divide as usual. The decimal point in the answer is placed directly above the decimal point in the dividend.

Chapter 3

Summary

1.39 .4 .7 5  2.5.3 25 97 75 2 25 2 25 0 m88 m88888888

many places as it takes to make it a whole number. We must then be sure to

5.



whole number. If it is not, we move the decimal point in the divisor to the right as



To begin a division problem with decimals, we make sure that the divisor is a

265

266

Chapter 3 Decimals

Changing Fractions to Decimals [3.5] 4  because 6.  15  0.26

To change a fraction to a decimal, we divide the numerator by the denominator.

m88 m88888888

.266 .0 0 0  154 30 1 00 90 100 90 10

Changing Decimals to Fractions [3.5] 781 7. 0.781   1,000

To change a decimal to a fraction, we write the digits to the right of the decimal point over the appropriate power of 10.

Square Roots [3.6] 8. 49   7 because 72  7  7  49

, is the number we square to The square root of a positive number a, written a get a.

Pythagorean Theorem [3.6] In any right triangle, the length of the longest side (the hypotenuse) is equal to the square root of the sum of the squares of the two shorter sides.

c

b 90° a

c = a2 + b2

Chapter 3

Review

Give the place value of the 7 in each of the following numbers. [3.1]

1. 36.007

2. 121.379

Write each of the following as a decimal number. [3.1]

3. Thirty-seven and forty-two ten thousandths

4. One hundred and two hundred two hundred thousandths

Round 98.7654 to the nearest: [3.1]

5. hundredth

6. hundred

Perform the following operations. [3.2, 3.3, 3.4]

7. 3.78  2.036

11. 29.07  3.8

8. 11.076  3.297

12. 0.7134  0.58

9. 6.7  5.43

13. 65 460.85 

10. 0.89(24.24)

14. (0.25)3

Write as a decimal. [3.5] 7 8

3 16

15. 

16. 

Write as a fraction in lowest terms. [3.5]

17. 0.705

18. 0.246

Write as a mixed number. [3.5]

19. 14.125

20. 5.05

Simplify each of the following expressions as much as possible. [3.5]

21. 3.3  4(0.22)

22. 54.987  2(3.05  0.151)

5 3

23. 125   4

3 5

2 5

24.  (0.9)   (0.4)

Simplify each of the following expressions as much as possible. [3.5]

25. 325 

26. 64   36 

27. 425   381 

28.

  49 16

Chapter 3

Review

267

Chapter 3

Cumulative Review

Simplify.

1. 3,781  298

2. 903  576

5. 241 4 9 .2 8 

6.   

5 14

3 5

2 7

3. 56(287)

4. 2.106  1.79

7. 4.3(12.96)

8. 1,292  17

15 21

9.   

63 4

11. Change  to a mixed number.

10. Round 463,612 to the nearest thousand.

1 5

1 2

12. Change 2  to an improper fraction.

13. Find the product of 2  and 8.

14. Change each decimal into a fraction. Decimal Decimal

0.125 0.125

0.250 0.250

0.375 0.375

0.500 0.500

0.625 0.625

0.750 0.750

0.875 0.875

1 1

Fraction Fraction

15. Give the quotient of 72 and 8.

16. Identify the property or properties used in the following: 2  (x  3)  (2  3)  x

17. Translate into symbols, then simplify: Three times the sum of 13 and 4 is 51.

19. True or False? Adding the same number to the numerator and denominator of a fraction produces an equivalent fraction.

268

Chapter 3 Decimals

120 70

18. Reduce: 

Chapter 3

Cumulative Review

269

Simplify. 6  2(4) 8  10

24.

 2    4  1

3

1

2 3 1

21. 

20. 6(4)2  8(2)3

2



1 3

1 2

25. 3   

2

22. 10   6 

2 3

4 5

23.  (0.45)   (0.8)

4 2  4  1

3

26. Average Score Lorena has scores of 83, 85, 79, 93, and 80 on her first five math tests. What is her average

27. Geometry Find the length of the hypotenuse of a right triangle with shorter sides of 6 in. and 8 in.

score for these five tests?

3

28. Recipe A muffin recipe calls for 2 4 cups of flour. If the recipe is tripled, how many cups of flour will be needed?

29. Hourly Wage If you earn $384 for working 40 hours, what is your hourly wage?

Chapter 3

Test

1. Write the decimal number 5.053 in words.

2. Give the place value of the 4 in the number 53.0543.

3. Write seventeen and four hundred six ten thousandths

4. Round 46.7549 to the nearest hundredth.

as a decimal number.

Perform the following operations.

5. 7  0.6  0.58

6. 12.032  5.976

23 25

9. Write  as a decimal.

8. 22.672  2.6

7. 5.7(6.24)

10. Write 0.56 as a fraction in lowest terms.

Simplify each expression as much as possible.

11. 5.2(2.8  0.02)

3 5

2 3

14.  (0.6)   (0.15)

12. 5.2  3(0.17)

13. 23.852  3(2.01  0.231)

15. 236   364 

16.

17. A person purchases $8.47 worth of goods at a drugstore. If a $20 bill is used to pay for the purchases, how

  81 25

18. If coffee sells for $6.99 per pound, how much will 3.5 pounds of coffee cost?

much change is received?

19. If a person earns $262 for working 40 hours, what is the person’s hourly wage?

20. Find the length of the hypotenuse of the right triangle below.

3 in.

4 in.

270

Chapter 3 Decimals

Chapter 3 Projects DECIMALS

GROUP PROJECT Unwinding the Spiral of Roots Number of People Time Needed Equipment Background

2–3 8–12 minutes Pencil, ruler, graph paper, scissors, and tape The diagram below is called the Spiral of Roots. We can use the Spiral of Roots to visualize PhotoDisc/Getty Images

square roots of whole numbers.

1

1

1

1

4

3

2

5

6

1

1

7

1

1

8

9 10

1

11

1 1

Procedure 1.

Carefully cut out each triangle from the Spi-

side of each triangle should fit in each of the

ral of Roots above.

1-unit spaces on the x-axis.

2. Line up the triangles horizontally on the co-

3. On the coordinate system, plot a point at

ordinate system shown here so that the side

the tip of each triangle. Then, connect these

of length 1 is on the x-axis and the hy-

points to create a line graph. Each vertical

potenuse is on the left. Note that the first tri-

line has a length that is represented by the

angle is shown in place, and the outline of

square root of one of the first 10 counting

the second triangle is next to it. The 1-unit

numbers.

Chapter 3

Projects

271

RESEARCH PROJECT The Wizard of Oz fortunately, the Scarecrow’s inability to recite

crow (played by Ray Bolger) sings “If I only had

the Pythagorean Theorem might lead one to

a brain.” Upon receiving a diploma from the

doubt the effectiveness of his diploma. Watch

great Oz, he rapidly recites a math theorem in

this scene in the movie. Write down the Scare-

an attempt to display his new knowledge. Un-

crow’s speech and explain the errors.

The Kobal Collection

In the 1939 movie The Wizard of Oz, the Scare-

272

Chapter 3 Decimals

A Glimpse of Algebra In the beginning of this chapter and in Chapter 1, we wrote numbers in expanded form. If we were to write the number 345 in expanded form and then in terms of powers of 10, it would look like this: 345  300  40  5  3  100  4  10  5  3  102  4  10  5 If we replace the 10’s with x’s in this last expression, we get what is called a polynomial. It looks like this: 3x2  4x  5 Polynomials are to algebra what whole numbers written in expanded form in terms of powers of 10 are to arithmetic. As in other expressions in algebra, we can use any variable we choose. Here are some other examples of polynomials: 4x  5

a2  5a  6

y 3  3y 2  3y  1

When we add two whole numbers, we add in columns. That is, if we add 345 and 234, we write one number under the other and add the numbers in the ones column, then the numbers in the tens column, and finally the numbers in the hundreds column. Here is how it looks. 3  102  4  10  5

345 234 579

or

2  102  3  10  4 5  102  7  10  9

We add polynomials in the same manner. If we want to add 3x2  4x  5 and 2x2  3x  4, we write one polynomial under the other, and then add in columns: 3x2  4x  5 2x2  3x  4 5x2  7x  9 The sum of the two polynomials is the polynomial 5x2  7x  9. We add only the digits. Notice that the variable parts (the letters) stay the same (just as the powers of 10 did when we added 345 and 234). Here are some more examples.

EXAMPLE 1 SOLUTION

PRACTICE PROBLEMS Add 3x  2x  6 and 4x  7x  3. 2

1. Add 2x2  4x  2 and 4x2  3x  5.

2

We write one polynomial under the other and add in columns: 3x2  2x  6 4x2  7x  3 7x2  9x  9

The sum of the two polynomials is 7x2  9x  9.

Answer 1. 6x2  7x  7

A Glimpse of Algebra

273

274

2. Add 3a  7 and 2a  6.

Chapter 3 Decimals

EXAMPLE 2 SOLUTION

Add 4a  2 and 5a  9.

We write one polynomial under the other and add in columns: 4a  2 5a  9 9a  11

3. Add 2x3  5x2  3x  6, 3x3  4x2  9x  8, and 4x3  2x2  3x  2.

EXAMPLE 3

Add 4x3  2x2  4x  1, 2x3  3x2  9x  6, and 2x3  2x2  2x  2.

SOLUTION

We add three polynomials the same way we add two of them. We

write them one under the other and add in columns: 4x3  2x2  4x  1 2x3  3x2  9x  6 2x3  2x2  2x  2 8x3  7x2  15x  9

4. Add 3y2  4y  6 and 6y2  2.

EXAMPLE 4 SOLUTION

Add 5y2  3y  6 and 2y2  3.

We write one polynomial under the other, so that the terms with y2

line up, and the terms without any y’s line up: 5y2  3y  6 2y2

3

7y2  3y  9

5. Add 5x3  7x2  3x  1 and 2x2  4x  1.

EXAMPLE 5 SOLUTION

Add 2x3  4x2  2x  6 and 3x2  2x  1.

Again, we line up terms with the same variable part and add: 2x3  4x2  2x  6 3x2  2x  1 2x  7x2  4x  7 3

Answers 2. 5a  13 3. 9x3  11x2  15x  16 4. 9y2  4y  8 5. 5x3  9x2  7x  2

A Glimpse of Algebra Problems

A Glimpse of Algebra Problems In each case, add the polynomials.

1. 4x2  2x  3

2. 3x2  4x  5

3. 2a  3

4. 5a  2

2x  7x  5

5x2  4x  3

3a  5

2a  1

2

5. 3x  4

6. 2x  1

7. 2y3  3y2  4y  5

8. 4y3  2y2  6y  7

2x  1

3x  2

3y3  2y2  5y  2

5y3  6y2  2y  8

4x  1

4x  3

9. Add 3x 2  4x  3 and 3x2  2.

10. Add 5x 2  6x  7 and 4x 2  2.

11. Add 3a2  4 and 7a  2.

12. Add 2a2  5 and 4a  3.

13. Add 5x 3  4x2  7x  3 and 3x2  9x  10.

14. Add 2x 3  7x2  3x  1 and 4x2  3x  8.

275

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4

Ratio and Proportion

Chapter Outline 4.1 Ratios 4.2 Rates and Unit Pricing 4.3 Solving Equations by Division 4.4 Proportions 4.5 Applications of Proportions 4.6 Similar Figures

Introduction The Eiffel Tower in Paris, France, is one of the most recognizable structures in the world. It was built in 1889 on the Champ de Mars beside the Seine River and named after its designer, engineer Gustave Eiffel. At that time it was the world’s tallest tower, measuring 300 meters. Today it remains the tallest building in Paris. This structure has inspired many reproductions, that is, towers built as replicas of the original Eiffel tower. The chart below shows the location and heights of some of these towers:

Eiffel Tower 300 meters

165 meters

18 meters Eiffel Tower (1889)

Paris Las Vegas Hotel (1999)

Paris, Tennessee (1993)

6 meters Paris, Michigan (1980)

As you can see, these replicas are all different sizes. In mathematics, we can use ratios to compare those different size towers. For instance, we say the largest height and smallest height in the chart are in a ratio of 50 to 1. In this chapter, we study ratios like this one. As you will see, ratios are very closely related to fractions and decimals, which we have already studied.

277

Chapter Pretest The Pretest below contains problems that are representative of the problems you will find in the chapter. Express each ratio as a fraction in lowest terms.

1. 15 to 25

3. 5 to 7

2. 400 to 150

4

4. 3.2 to 4.6

4

5. A car travels 434 miles in 7 hours. What is the rate of the car in miles per hour? 6. A 16-ounce container of heavy whipping cream costs $2.40. Find the price per ounce. Solve each proportion. 5 6

2 y

x 12

7.   

9 7

4 10

8.   

1  6 n 10.    8 1  9

6 x

9.   

11. A trucker drives his rig 480 miles in 8 hours. At this rate, how far will he travel in 12 hours? 12. A company reimburses its employees 36.5¢ for every mile of business travel. If an employee drives 150 miles, how much will she be reimbursed? Assume the figures presented are similar.

13. Find length x.

14. Find length BC. G 12

E

9

20

6

C

F

15 6

A

x

B

Getting Ready for Chapter 4 The problems below review material covered previously that you need to know in order to be successful in Chapter 4. Reduce to lowest terms. 16 48

320 160

1. 

2. 

Write as a decimal. 1 4

1

3. 

4.  8

Multiply or divide as indicated.

5. 5  13

6. 3(0.4)

9. 0.08  100 11. 125  2

7. 3.5(85) 10. 0.12  100

12. 1.39  2

1.99 1  2

13. 

Divide. Round answers to the nearest tenth.

15. 48  5.5

278

2 3

8.   6

Chapter 4 Ratio and Proportion

16. 75  11.5

2  3 14.  4  9

Ratios

4.1 Objectives A Express ratios as fractions in lowest

Introduction The ratio of two numbers is a way of comparing them. If we say that the ratio of two numbers is 2 to 1, then the first number is twice as large as the second number. For example, if there are 10 men and 5 women enrolled in a math class, then

terms.

B

Use ratios to solve application problems.

the ratio of men to women is 10 to 5. Because 10 is twice as large as 5, we can also say that the ratio of men to women is 2 to 1. We can define the ratio of two numbers in terms of fractions.

Examples now playing at

A Express Ratios as Fractions in Lowest Terms

MathTV.com/books

Definition A ratio is a comparison between two numbers and is represented as a fraction, where the first number in the ratio is the numerator and the second number in the ratio is the denominator. In symbols: If a and b are any two numbers,

a then the ratio of a to b is . b

(b  0)

We handle ratios the same way we handle fractions. For example, when we said that the ratio of 10 men to 5 women was the same as the ratio 2 to 1, we were actually saying 10 2    5 1

Reducing to lowest terms

Because we have already studied fractions in detail, much of the introductory material on ratios will seem like review.

EXAMPLE 1 SOLUTION

PRACTICE PROBLEMS Express the ratio of 16 to 48 as a fraction in lowest terms.

Because the ratio is 16 to 48, the numerator of the fraction is 16 and

the denominator is 48: 16 1    48 3

1. a. Express the ratio of 32 to 48 as a fraction in lowest terms.

b. Express the ratio of 3.2 to 4.8 as a fraction in lowest terms.

c. Express the ratio of 0.32 to

In lowest terms

0.48 as a fraction in lowest terms.

Notice that the first number in the ratio becomes the numerator of the fraction, and the second number in the ratio becomes the denominator.

STUDY SKILLS Continue to Set and Keep a Schedule Sometimes I find students do well at first and then become overconfident. They begin to put in less time with their homework. Don’t do it. Keep to the same schedule.

Answer 2 3

1. All are 

4.1 Ratios

279

280

Chapter 4 Ratio and Proportion

2. a. Give the ratio of 3 to 9 as a 5

10

fraction in lowest terms.

b. Give the ratio of 0.6 to 0.9 as a fraction in lowest terms.

EXAMPLE 2

2 4 Give the ratio of  to  as a fraction in lowest terms. 3 9 2 4 SOLUTION We begin by writing the ratio of  to  as a complex fraction. The 3 9 2 4 numerator is , and the denominator is . Then we simplify. 3 9 2  3 4 9 2 9      Division by 9 is the same as multiplication by 4 4 3 4  9 18   Multiply 12 3   2

3. a. Write the ratio of 0.06 to 0.12 as a fraction in lowest terms. b. Write the ratio of 600 to 1200 as a fraction in lowest terms.

EXAMPLE 3 SOLUTION

Reduce to lowest terms

Write the ratio of 0.08 to 0.12 as a fraction in lowest terms.

When the ratio is in reduced form, it is customary to write it with

whole numbers and not decimals. For this reason we multiply the numerator and the denominator of the ratio by 100 to clear it of decimals. Then we reduce to lowest terms.

Note

Another symbol used to denote ratio is the colon (:). The ratio of, say, 5 to 4 can be written as 5:4. Although we will not use it here, this notation is fairly common.

0.08 0.08  100    0.12 0.12  100 8   12 2   3

Multiply the numerator and the denominator by 100 to clear the ratio of decimals Multiply Reduce to lowest terms

Table 1 shows several more ratios and their fractional equivalents. Notice that in each case the fraction has been reduced to lowest terms. Also, the ratio that contains decimals has been rewritten as a fraction that does not contain decimals. TABLE 1

Ratio

Fraction 25  35 35  25 8  2 1  4  3  4 0.6  1.7

25 to 35 35 to 25 8 to 2

1 3  to  4 4 0.6 to 1.7

Fraction In Lowest Terms 5  7 7  5 4  We can also write this as just 4. 1 1  4 1 1 4 1  because  3  4  3  3 3  4 6 6 0.6  10  because    1.7  10 17 17

B Applications of Ratios 4. Suppose the basketball player in Example 4 makes 12 out of 16 free throws. Write the ratio again using these new numbers.

EXAMPLE 4

free throws he attempts. Write the ratio of the number of free throws he makes to the number of free throws he attempts as a fraction in lowest terms.

SOLUTION

Because he makes 12 out of 18, we want the ratio 12 to 18, or 12 2     18 3

Answers 2 3

2. Both are  3 4.  4

During a game, a basketball player makes 12 out of the 18

1 2

3. Both are 

Because the ratio is 2 to 3, we can say that, in this particular game, he made 2 out of every 3 free throws he attempted.

4.1 Ratios

281

A solution of alcohol and water contains 15 milliliters of

5. A solution of alcohol and water

water and 5 milliliters of alcohol. Find the ratio of alcohol to water, water to alco-

contains 12 milliliters of water and 4 milliliters of alcohol. Find the ratio of alcohol to water, water to alcohol, and water to total solution. Write each ratio as a fraction and reduce to lowest terms.

EXAMPLE 5

hol, water to total solution, and alcohol to total solution. Write each ratio as a fraction and reduce to lowest terms.

SOLUTION There are 5 milliliters of alcohol and 15 milliliters of water, so there are 20 milliliters of solution (alcohol  water). The ratios are as follows: The ratio of alcohol to water is 5 to 15, or 1 5     3 15

In lowest terms

The ratio of water to alcohol is 15 to 5, or 15 3     5 1

5 mL

In lowest terms

The ratio of water to total solution is 15 to 20, or 15 3     20 4

In lowest terms

The ratio of alcohol to total solution is 5 to 20, or 1 5     4 20

In lowest terms

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. In your own words, write a definition for the ratio of two numbers. 2. What does a ratio compare? 3. What are some different ways of using mathematics to write the ratio of a to b? 4. When will the ratio of two numbers be a complex fraction?

Answer 1 3 3 3 1 4

5. , , 

This page intentionally left blank

4.1 Problem Set

Problem Set 4.1 A Write each of the following ratios as a fraction in lowest terms. None of the answers should contain decimals. [Examples 1–3] 1. 8 to 6

2. 6 to 8

3. 64 to 12

4. 12 to 64

5. 100 to 250

6. 250 to 100

7. 13 to 26

8. 36 to 18

3 4

1 4

10.  to 

6 5

6 7

14.  to 

9.  to 

13.  to 

2 3

5 3

5 8

3 8

11.  to 

5 3

1 3

15. 2 to 3

16. 5 to 1

1 2

1 2

7 3

1 2

6 3

9 5

11 5

12.  to 

1 2

1 4

3 4

17. 2 to 

18.  to 3

19. 0.05 to 0.15

20. 0.21 to 0.03

21. 0.3 to 3

22. 0.5 to 10

23. 1.2 to 10

24. 6.4 to 0.8

283

284

Chapter 4 Ratio and Proportion

25. a. What is the ratio of shaded squares to nonshaded squares?

squares?

b. What is the ratio of shaded squares to total squares?

c. What is the ratio of nonshaded squares to total squares?

B

26. a. What is the ratio of shaded squares to nonshaded

Applying the Concepts

b. What is the ratio of shaded squares to total squares?

c. What is the ratio of nonshaded squares to total squares?

[Examples 4, 5]

27. Biggest Hits The chart shows the number of hits for the

28. Google Earth The Google Earth image shows Crater

three best charting artists in the United States. Use the

Lake National Park in Oregon. The park covers 266

information to find the ratio of hits the Beach Boys had

square miles and the lake covers 20 square miles. What

to hits the Beatles had.

is the ratio of the park’s area to the lake’s area? Write your answer as a decimal.

Best Charting Artists Of All Time

70

The Beatles Rolling Stones Beach Boys

57 55

Source: Tenmojo.com According to Music Information Database

Write each of the following ratios as a fraction in lowest terms. None of the answers should contain decimals.

29. 100 mg to 5 mL

30. 25 g to 1 L

31. 375 mg to 10 mL

32. 450 mg to 20 mL

285

4.1 Problem Set 33. Family Budget A family of four budgeted the following amounts for some of their monthly bills:

34. Nutrition One cup of breakfast cereal was found to contain the following nutrients:

Food bill $400

21.0 g

Carbohydrates

Gas bill $100 4.4 g

Minerals

Utilities bill $150

Vitamins

Rent $650

0.6 g 1.0 g

Water

a. What is the ratio of the rent to the food bill?

Protein

2.0 g 0

2

4

6

8 grams

18

20

22

b. What is the ratio of the gas bill to the food bill? a. Find the ratio of water to protein. c. What is the ratio of the utilities bill to the food bill? b. Find the ratio of carbohydrates to protein. d. What is the ratio of the rent to the utilities bill? c. Find the ratio of vitamins to minerals.

d. Find the ratio of protein to vitamins and minerals.

35. Profit and Revenue The following bar chart shows the

36. Geometry Regarding the diagram below, AC represents

profit and revenue of the Baby Steps Shoe Company

the length of the line segment that starts at A and ends

each quarter for one year.

at C. From the diagram we see that AC  8.

$12,000

D Profit

Revenue $10,500

$10,000

B $8,400 $7,500

$8,000

9 6

$6,000 $6,000

$3,500

$4,000

A

8

C

4

$2,100 $1,500

$2,000

a. Find the ratio of BC to AC.

$1,000 $0

Q1

Q2

Q3

Q4

Find the ratio of revenue to profit for each of the fol-

b. What is the length AE?

lowing quarters. Write your answer in lowest terms.

a. Q1

b. Q2

c. Q3

d. Q4

e. Find the ratio of revenue to profit for the entire year.

c. Find the ratio of DE to AE.

E

286

Chapter 4 Ratio and Proportion

37. Major League Baseball The following table shows the

38. Buying an iPod™ The hard drive of an Apple iPod deter-

number of games won during the 2007 baseball season

mines how many songs you will be able to store and

by several National League teams.

carry around with you. The table below compares the size of the hard-drive, song capacity and cost of three

Team

popular iPods.

Number of Wins

New York Mets Atlanta Braves Washington Nationals St. Louis Cardinals Houston Astros Arizona Diamondbacks Cincinnati Reds

88 84 73 78 73 90 72

iPod Type Shuffle Nano Classic

a. What is the ratio of wins of the New York Mets to the

Hard-Drive Size

Number of Songs

Cost

2 GB 4 GB 80 GB

500 songs 1000 songs 20,000 songs

$69.00 $149.00 $249.00

a. What is the ratio of hard-drive size between the

St. Louis Cardinals?

Shuffle and the Nano? Between the Shuffle and the Classic?

b. What is the ratio of wins of the Washington Nation-

b. What is the ratio of number of songs between the

als to the Houston Astros?

Shuffle and the Nano? Between the Shuffle and the

c. What is the ratio of wins of the Cincinnati Reds to

Classic?

the Atlanta Braves?

Getting Ready for the Next Section The following problems review material from a previous section. Reviewing these problems will help you with the next section. Write as a decimal. 90 39.  5

1.23 2

120 3

1.39

43. 

125 2

40. 

88 0 .5

45. 

44.  2

2 10

41. 

42. 

1.99

46 0.25

92 0.25

47. 

46.  0.5

48. 

Divide. Round answers to the nearest thousandth.

49. 0.48  5.5

50. 0.75  11.5

51. 2.19  46

52. 1.25  50

Maintaining Your Skills Multiply and divide as indicated. 3 4

5 6

53.   

65

108

72

273

57.   

7 8

11 16

54.   32

165

24 195

58.    84

1 8

55.   

3

1

4

8

59.     16

1 3

56. 13  

1

1 12

60.     6 4

Rates and Unit Pricing Here is the first paragraph of an article that appeared in USA Today in 2003. Culture Clash

DANNON YOGURT

Dannon recently shrank its 8-ounce cup of yo-

Old

New

8 ounces

6 ounces

Container cost

88 cents

72 cents

Price per ounce

11 cents

12 cents

gurt by 25% to 6 ounces—but cut its suggested retail price by only 20% from 89 cents to 71 cents, which would raise the unit price a penny an ounce—9%—to 12 cents. At the Hoboken store, which charges more than Dannon’s suggested prices, the unit price went from 12 cents to 13 cents with the size change.

Size

4.2 Objectives A Express rates as ratios. B Use ratios to write a unit price.

Examples now playing at

MathTV.com/books

Price difference per ounce: 9%

In this section we cover material that will give you a better understanding of the information in this article. We start this section with a discussion of rates, then we move on to unit pricing.

A Rates Whenever a ratio compares two quantities that have different units (and neither unit can be converted to the other), then the ratio is called a rate. For example, if we were to travel 120 miles in 3 hours, then our average rate of speed expressed as the ratio of miles to hours would be 120 miles 40 miles    3 hours 1 hour

Divide the numerator and the denominator by 3 to reduce to lowest terms

40 miles The ratio  can be expressed as 1 hour miles 40  hour

or

40 miles/hour

or

40 miles per hour

A rate is expressed in simplest form when the numerical part of the denominator is 1. To accomplish this we use division.

EXAMPLE 1

PRACTICE PROBLEMS A train travels 125 miles in 2 hours. What is the train’s rate

SOLUTION

1. A car travels 107 miles in 2 hours. What is the car’s rate in miles per hour?

in miles per hour? The ratio of miles to hours is 125 miles miles   62.5  2 hours hour

Divide 125 by 2

 62.5 miles per hour If the train travels 125 miles in 2 hours, then its average rate of speed is 62.5 miles per hour.

EXAMPLE 2

A car travels 90 miles on 5 gallons of gas. Give the ratio of

SOLUTION

The ratio of miles to gallons is 90 miles miles   18  5 gallons gallon

2. A car travels 192 miles on 6 gallons of gas. Give the ratio of miles to gallons as a rate in miles per gallon.

miles to gallons as a rate in miles per gallon.

Divide 90 by 5 Answers 1. 53.5 miles/hour 2. 32 miles/gallon

 18 miles/gallon The gas mileage of the car is 18 miles per gallon.

4.2 Rates and Unit Pricing

287

288

Chapter 4 Ratio and Proportion

B Unit Pricing One kind of rate that is very common is unit pricing. Unit pricing is the ratio of price to quantity when the quantity is one unit. Suppose a 1-liter bottle of a certain soft drink costs $1.19, whereas a 2-liter bottle of the same drink costs $1.39. Which is the better buy? That is, which has the lower price per liter? $1.19   $1.19 per liter 1 liter $1.39   $0.695 per liter 2 liters The unit price for the 1-liter bottle is $1.19 per liter, whereas the unit price for the 2-liter bottle is 69.5¢ per liter. The 2-liter bottle is a better buy.

EXAMPLE 3

3. A supermarket sells vegetable juice in three different containers at the following prices: 5.5 ounces, 48¢ 11.5 ounces, 75¢ 46 ounces, $2.19 Give the unit price in cents per ounce for each one. Round to the nearest tenth of a cent, if necessary.

A supermarket sells low-fat milk in three different con-

tainers at the following prices: 1 gallon

$3.59

1  2

$1.99

gallon

1 quart

$1.29

1

(1 quart  4 gallon)

$3.59

$1.99

$1.29

Give the unit price in dollars per gallon for each one.

SOLUTION

1 Because 1 quart   gallon, we have 4 $3.59 $3.59 1-gallon container     $3.59 per gallon 1 gallon 1 gallon 1  2

-gallon container

1-quart container

$1.99 $1.99     $3.98 per gallon 1 0.5 gallon  gallon 2 $1.29 $1.29     $5.16 per gallon 1 quart 0.25 gallon

The 1-gallon container has the lowest unit price, whereas the 1-quart container has the highest unit price.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. A rate is a special type of ratio. In your own words, explain what a rate is. 2. When is a rate written in simplest terms? 3. What is unit pricing? 4. Give some examples of rates not found in your textbook.

Answer 3. 8.7¢/ounce, 6.5¢/ounce, 4.8¢/ounce

4.2 Problem Set

289

Problem Set 4.2 A Express each of the following rates as a ratio with the given units. [Examples 1, 2] 1. Miles/Hour A car travels 220 miles in 4 hours. What is the rate of the car in miles per hour?

2. Miles/Hour A train travels 360 miles in 5 hours. What is the rate of the train in miles per hour?

EAST OKLAHOMA CITY

220 MILES

4 hours from Dallas 3. Kilometers/Hour It takes a car 3 hours to travel 252 kilometers. What is the rate in kilometers per hour?

4. Kilometers/Hour In 6 hours an airplane travels 4,200 kilometers. What is the rate of the airplane in kilometers per hour?

5. Gallons/Second The flow of water from a water faucet can fill a 3-gallon container in 15 seconds. Give the

6. Gallons/Minute A 225-gallon drum is filled in 3 minutes. What is the rate in gallons per minute?

ratio of gallons to seconds as a rate in gallons per second.

7. Liters/Minute It takes 4 minutes to fill a 56-liter gas tank. What is the rate in liters per minute?

8. Liters/Hour The gas tank on a car holds 60 liters of gas. At the beginning of a 6-hour trip, the tank is full. At the end of the trip, it contains only 12 liters. What is the rate at which the car uses gas in liters per hour?

9. Miles/Gallon A car travels 95 miles on 5 gallons of gas. Give the ratio of miles to gallons as a rate in miles per

10. Miles/Gallon On a 384-mile trip, an economy car uses 8 gallons of gas. Give this as a rate in miles per gallon.

gallon.

000950 5 gallons

95 miles

11. Miles/Liter The gas tank on a car has a capacity of 75

12. Miles/Liter A car pulling a trailer can travel 105 miles on

liters. On a full tank of gas, the car travels 325 miles.

70 liters of gas. What is the gas mileage in miles per

What is the gas mileage in miles per liter?

liter?

290

Chapter 4 Ratio and Proportion

13. Gas Prices The snapshot shows the gas prices for the

14. Pitchers The chart shows the active major league pitch-

different regions of the United States. If a man bought

ers with the most career strikeouts. If Pedro Martinez

12 gallons of gas for $48.72, where might he live?

pitched 2,783 innings, how many strikeouts does he throw per inning? Round to the nearest hundredth.

King of the Hill

Average Price per Gallon of Gasoline, July 2008 $4.44

Randy Johnson

$4.10

4,789

Rodger Clemens

$4.07

Greg Maddux

$4.06

Pedro Martinez

4,672 3,371 3,117

$3.96

Source: www.mlb.com, November 2008

Source: http://www.fueleconomy.gov

Nursing Intravenous (IV) infusions are often ordered in either milliliters per hour or milliliters per minute. 15. What was the infusion rate in milliliters per hour if it

16. What was the infusion rate in milliliters per minute if 42

took 5 hours to administer 2,400 mL?

B

Unit Pricing

milliliters were administered in 6 minutes?

[Example 3]

17. Cents/Ounce A 20-ounce package of frozen peas is

18. Dollars/Pound A 4-pound bag of cat food costs $8.12.

priced at 99¢. Give the unit price in cents per ounce.

Give the unit price in dollars per pound.

19. Best Buy Find the unit price in cents per diaper for each of the packages shown here. Which is the better buy? Round to the nearest tenth of a cent.

20. Best Buy Find the unit price in cents per pill for each of the packages shown here. Which is the better buy? Round to the nearest tenth of a cent. 100 pills

$5.99

225 pills

$13.96

4.2 Problem Set

291

Currency Conversions There are a number of online calculators that will show what the money in one country is worth in another country. One such converter, the XE Universal Currency Converter®, uses live, up-to-the-minute currency rates. Use the information shown here to determine what the equivalent to one U.S. dollar for each of the following denominations. Round to the nearest thousandth, wherre necessary.

21. $100.00 U.S. dollars are equivalent to 64.582 euros 22. $50.00 U.S. dollars are equivalent to $51.0775 Canadian dollars 23. $40.00 U.S. dollars are equivalent to 20.3765 British pounds 24. $25.00 U.S. dollars are equivalent to 2704.0125 Japanese yen

25. Food Prices Using unit rates is a way to compare prices

26. Cell Phone Plans All cell phone plans are not created

of different sized packages to see which price is really

equal. The number of minutes and the monthly charges

the best deal. Suppose we compare the cost of a box of

can vary greatly. The table shows four plans presented

Cheerios sold at three different stores for the following

by four different cell phone providers.

prices: Carrier Store

Size

Cost

A

11.3 ounce box

$4.00

B

18 ounce box

$4.99

C

180 ounce case

$52.90

AT&T

Sprint

T Mobile

Verizon

Nation 450

Sprint Basic

Individual Value

Nationwide Basic

Monthly minutes

450

200

600

450

Monthly cost

$39.99

$29.99

$39.99

$39.99

Plan name

Which size is the best buy? Give the cost per ounce for

Plan cost per minute

that size. Find the cost per minute for each plan. Based on your results, which plan should you go with?

1

27. Miles/Hour A car travels 675.4 miles in 122 hours. Give

28. Miles/Hour At the beginning of a trip, the odometer on a

the rate in miles per hour to the nearest hundredth.

car read 32,567.2 miles. At the end of the trip, it read 1

32,741.8 miles. If the trip took 44 hours, what was the rate of the car in miles per hour to the nearest tenth?

29. Miles/Gallon If a truck travels 128.4 miles on 13.8 gallons of gas, what is the gas mileage in miles per gallon? (Round to the nearest tenth.)

30. Cents/Day If a 15-day supply of vitamins costs $1.62, what is the price in cents per day?

292

Chapter 4 Ratio and Proportion

Hourly Wages Jane has a job at the local Marcy’s depart-

Department Store Rate of Pay $350

ment store. The graph shows how much Jane earns for

320

working 8 hours per day for 5 days. $300

31. What is her daily rate of pay? (Assume she works

256

8 hours per day.)

32. What is her weekly rate of pay? (Assume she works 5 days per week.)

33. What is her annual rate of pay? (Assume she works 50 weeks per year.)

Dollars earned

$250 192

$200 $150

128

$100 64 $50 $0

34. What is her hourly rate of pay? (Assume she works 8

1

hours per day.)

2

3

4

5

Days worked

Getting Ready for the Next Section Solve each equation by finding a number to replace n that will make the equation a true statement.

35. 2  n  12

36. 3  n  27

37. 6  n  24

38. 8  n  16

39. 20  5  n

40. 35  7  n

41. 650  10  n

42. 630  7  n

Maintaining Your Skills Add and subtract as indicated. 1

3

2

8

43.   

11

9 10

47.    12

7

1

6

3

44.   

13

1 10

48.    15

2

3

5

8

5

1

4

6

3

3

45.   

5

3

8

4

7

1

8

8

46.   

49.     

1 16

50.     

Extending the Concepts 51. Unit Pricing The makers of Wisk liquid detergent cut the size of its popular midsize jug from 100 ounces (3.125 quarts) to 80 ounces (2.5 quarts). At

WISK LAUNDRY DETERGENT

the same time it lowered the price from $6.99 to $5.75. Fill in the table below and use your results to decide which of the two sizes is the better buy.

Size Container cost Price per quart

Old

New

100 ounces $6.99

80 ounces $5.75

Solving Equations by Division In Chapter 1 we solved equations like 3  n  12 by finding a number with which to replace n that would make the equation a true statement. The solution for the equation 3  n  12 is n  4, because the equation

3  n  12

becomes

3  4  12

or

12  12

Objectives A Divide expressions containing a variable.

B

n4

when

4.3 Solve equations using division.

A true statement

Examples now playing at

The problem with this method of solving equations is that we have to guess at the

MathTV.com/books

solution and then check it in the equation to see if it works. In this section we will develop a method of solving equations like 3  n  12 that does not require any guessing. In Chapter 2 we simplified expressions such as 22357  25 by dividing out any factors common to the numerator and the denominator. For example:

2 23 57    2  3  7  42 5  2

The same process works with expressions that have variables for some of their factors. For example, the expression 2  n  7  11  n  11 can be simplified by dividing out the factors common to the numerator and the denominator—namely, n and 11: 2 n7 11   2  7  14  n 11

EXAMPLE 1 SOLUTION

PRACTICE PROBLEMS Divide the expression 5  n by 5.

1. Divide the expression 8  n by 8.

Applying the method above, we have: n 5 5  n divided by 5 is   n  5

If you are having trouble understanding this process because there is a variable involved, consider what happens when we divide 6 by 2 and when we divide 6 by 3. Because 6  2  3, when we divide by 2 we get 3. Like this: 6 3 2      3 2  2 When we divide by 3, we get 2: 6 2 3      2 3 3 

EXAMPLE 2 SOLUTION

Divide 7  y by 7.

2. Divide 3  y by 3.

Dividing by 7, we have: y 7 7  y divided by 7 is   y  7

Answers 1. n 2. y

4.3 Solving Equations by Division

293

294

Note

The choice of the letter we use for the variable is not important. The process works just as well with y as it does with n. The letters used for variables in equations are most often the letters a, n, x, y, or z.

Chapter 4 Ratio and Proportion We can use division to solve equations such as 3  n  12. Notice that the left side of the equation is 3  n. The equation is solved when we have just n, instead of 3  n, on the left side and a number on the right side. That is, we have solved the equation when we have rewritten it as n  a number We can accomplish this by dividing both sides of the equation by 3: n 3 12    3  3

Divide both sides by 3

n4

Note

In the last chapter of this book, we will devote a lot of time to solving equations. For now, we are concerned only with equations that can be solved by division.

Because 12 divided by 3 is 4, the solution to the equation is n  4, which we know to be correct from our discussion at the beginning of this section. Notice that it would be incorrect to divide just the left side by 3 and not the right side also. Whenever we divide one side of an equation by a number, we must also divide the other side by the same number.

EXAMPLE 3 3. Solve the equation 8  n  40 by dividing both sides by 8.

SOLUTION

Solve the equation 7  y  42 for y by dividing both sides by 7.

Dividing both sides by 7, we have: y 7 42     7  7 y6

We can check our solution by replacing y with 6 in the original equation: when

4. Solve for a: 35  7  a

7  y  42

becomes

7  6  42

or

42  42

EXAMPLE 4 SOLUTION

y6

the equation

A true statement

Solve for a: 30  5  a

Our method of solving equations by division works regardless of

which side the variable is on. In this case, the right side is 5  a, and we would like it to be just a. Dividing both sides by 5, we have: 30 a 5     5  5 6a The solution is a  6. (If 6 is a, then a is 6.) We can write our solutions as improper fractions, mixed numbers, or decimals. Let’s agree to write our answers as either whole numbers, proper fractions, or mixed numbers unless otherwise stated.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. In your own words, explain what a solution to an equation is. 2  n  7  11 2. What number results when you simplify ? n  11 3. What is the result of dividing 7  y by 7? Answers 3. 5 4. 5

4. Explain how division is used to solve the equation 30  5  a.

4.3 Problem Set

295

Problem Set 4.3 Simplify each of the following expressions by dividing out any factors common to the numerator and the denominator and then simplifying the result. 3557 35

2. 

2  2  n  7  11 2  n  11

6. 

1. 

5. 

4y 4

9. 

22357 257

3. 

2n335 n5

4. 

3  n  7  13  17 n  13  17

7. 

35n77 3n7

9n 9

8. 

8a 8

7x 7

10. 

Solve each of the following equations by dividing both sides by the appropriate number. Be sure to show the division in each case.

11. 4  n  8

12. 2  n  8

13. 5  x  35

14. 7  x  35

15. 3  y  21

16. 7  y  21

17. 6  n  48

18. 16  n  48

19. 5  a  40

20. 10  a  40

21. 3  x  6

22. 8  x  40

23. 2  y  2

24. 2  y  12

25. 3  a  18

26. 4  a  4

27. 5  n  25

28. 9  n  18

29. 6  2  x

30. 56  7  x

31. 42  6  n

32. 30  5  n

33. 4  4  y

34. 90  9  y

35. 63  7  y

36. 3  3  y

37. 2  n  7

38. 4  n  10

296

Chapter 4 Ratio and Proportion

39. 6  x  21

40. 7  x  8

41. 5  a  12

42. 8  a  13

43. 4  7  y

44. 3  9  y

45. 10  13  y

46. 9  11  y

47. 12  x  30

48. 16  x  56

49. 21  14  n

50. 48  20  n

Getting Ready for the Next Section Reduce. 6 8

17 34

51. 

52. 

Multiply. 2

54.   6

53. 3(0.4)

3

Divide.

55. 65  10

56. 1.2  8

Maintaining Your Skills Write each fraction or mixed number as an equivalent decimal number. 3 4

58. 

3 100

62. 

57. 

61. 

2 5

59. 5

1 2

2 50

63. 

3 8

1 4

60. 8

5 8

64. 

Write each decimal as an equivalent proper fraction or mixed number.

65. 0.34

66. 0.08

67. 2.4

68. 5.05

69. 1.75

70. 3.125

71. 0.875

72. 0.375

Proportions Millions of people are turning to the Internet to view music videos of their favorite musician. Many Web sites offer different sizes of video based on the speed of a user’s Internet connection. Even though the figures below are not the same size, their sides are proportional. Later in this chapter we will use proportions to

4.4 Objectives A Name the terms in a proportion. B Use the fundamental property of

proportions to solve a proportion.

find the unknown height in the larger figure.

Image: BigStockPhoto.com © Devanne Philippe

Music Video

Examples now playing at

Music Video

MathTV.com/books h

120



+ –

160

+

400

In this section we will solve problems using proportions. As you will see later in this chapter, proportions can model a number of everyday applications.

Definition a c A statement that two ratios are equal is called a proportion. If  and  are b d two equal ratios, then the statement a

c

b

d

   is called a proportion.

A Terms of a Proportion Each of the four numbers in a proportion is called a term of the proportion. We number the terms of a proportion as follows:

First term 88n a c m88 Third term    Second term 88n b d m88 Fourth term The first and fourth terms of a proportion are called the extremes, and the second and third terms of a proportion are called the means. a c    d m888 Extremes

Means 888n b

EXAMPLE 1 and the extremes.

SOLUTION

PRACTICE PROBLEMS 3 6 In the proportion   , name the four terms, the means, 4 8

the extremes.

The terms are numbered as follows: First term  3

Third term  6

Second term  4

Fourth term  8

2 6 3 9 the four terms, the means, and

1. In the proportion   , name

The means are 4 and 6; the extremes are 3 and 8.

Answer 1. See solutions section.

4.4 Proportions

297

298

Chapter 4 Ratio and Proportion The final thing we need to know about proportions is expressed in the following property.

B The Fundamental Property of Proportions Fundamental Property of Proportions In any proportion, the product of the extremes is equal to the product of the means. This property is also referred to as the means/extremes property, and in symbols, it looks like this: a c If    b d

2. Verify the fundamental property of proportions for the following proportions. 5 6

EXAMPLE 2 3 4

1 3

6 8

a.   

15 18

13 39

Verify the fundamental property of proportions for the fol-

lowing proportions.

a.    b.   

then ad  bc

SOLUTION

17 34

1 2

b.   

We verify the fundamental property by finding the product of the

means and the product of the extremes in each case.

2 

3  2 c. 

5

5  3

0.12 2 d.    0.18 3

Proportion

Product of the Means

Product of the Extremes

a.

3 6    4 8

4  6  24

3  8  24

b.

17 1    34 2

34  1  34

17  2  34

For each proportion the product of the means is equal to the product of the extremes. We can use the fundamental property of proportions, along with a property we encountered in Section 4.3, to solve an equation that has the form of a proportion.

A Note on Multiplication Previously, we have used a multiplication dot to indicate multiplication, both with whole numbers and with variables. A more compact form for multiplication involving variables is simply to leave out the dot. 3. Find the missing term: 3 4

9 x

a.   

That is, 5  y  5y and 10  x  y  10xy.

EXAMPLE 3

5 3 b.    8 x

Note

In some of these problems you will be able to see what the solution is just by looking the problem over. In those cases it is still best to show all the work involved in solving the proportion. It is good practice for the more difficult problems.

Solve for x.

2 4    3 x

SOLUTION

Applying the fundamental property of proportions, we have If then

2 4    3 x 2x34 2x  12

The product of the extremes equals the product of the means Multiply

The result is an equation. We know from Section 4.3 that we can divide both sides of an equation by the same nonzero number without changing the solution

Answer 2. See solutions section.

to the equation. In this case we divide both sides by 2 to solve for x:

299

4.4 Proportions 2x  12 x 2 12    2  2

Divide both sides by 2

x6

Simplify each side

The solution is 6. We can check our work by using the fundamental property of proportions:

888

88

828 84 88 8888  888 8 8 888 3 6 88

8

12

m8

n

12

Product of the means

Product of the extremes

Because the product of the means and the product of the extremes are equal, our work is correct.

EXAMPLE 4 SOLUTION

5 10 Solve for y:    y 13 We apply the fundamental property and solve as we did in Example

2 y

8 19

4. Solve for y:   

3: 5 10     y 13

If then

5 13  y  10 65  10y

The product of the extremes equals the product of the means Multiply 5  13

65 10y      10 10 

Divide both sides by 10

6.5  y

65  10  6.5

The solution is 6.5. We could check our result by substituting 6.5 for y in the original proportion and then finding the product of the means and the product of the extremes.

EXAMPLE 5 SOLUTION

n 0.4 Find n if   . 3 8 We proceed as we did in the previous two examples: n 0.4    3 8

If then

n  8  3(0.4)

n 0.3 6 15 0.35 7 b.    n 100

a.   

The product of the extremes equals the product of the means

8n  1.2

3(0.4)  1.2

n 8 1.2    8  8

Divide both sides by 8

n  0.15

5. Find n

1.2  8  0.15

The missing term is 0.15.

Answers 3. a. 12 b. 4.8 5. a. 0.12 b. 5

4.

4.75

300

Chapter 4 Ratio and Proportion

6. Solve for x: a.

3  4   x 7 8 6

15

3  5

x

2  3 x Solve for x:    5 6 We begin by multiplying the means and multiplying the extremes: 2  3 x    If 5 6

EXAMPLE 6 SOLUTION

b.   

then

2   6  5  x 3 45x 4 x 5     5  5

The product of the extremes equals the product of the means 2   6  4 3 Divide both sides by 5

4   x 5 4 The missing term is , or 0.8. 5 b

7. Solve   0.5

EXAMPLE 7

18

SOLUTION

b Solve   2. 15 Since the number 2 can be written as the ratio of 2 to 1, we can

write this equation as a proportion, and then solve as we have in the examples above. b   2 15 2 b     1 15 b  1  15  2

Write 2 as a ratio Product of the extremes equals Product of the means

b  30 The procedure for finding a missing term in a proportion is always the same. We first apply the fundamental property of proportions to find the product of the extremes and the product of the means. Then we solve the resulting equation.

STUDY SKILLS Continue to List Difficult problems You should continue to list and rework the problems that give you the most difficulty. It is this list that you will use to study for the next exam. Your goal is to go into the next exam knowing that you can successfully work any problem from your list of difficult problems.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. In your own words, give a definition of a proportion. 4 2 2. In the proportion   , name the means and the extremes. x 5 3. State the Fundamental Property of Proportions in words and in symbols. 4 2 4. For the proportion   , find the product of the means and the prodx 5 uct of the extremes.

Answers 6 7

3 2

6. a.  b.  7. 9

301

4.4 Problem Set

Problem Set 4.4 A For each of the following proportions, name the means, name the extremes, and show that the product of the means is equal to the product of the extremes. [Examples 1, 2] 1 3

5 15

6 12

1 2

3.   

10 25

2 5

4.   

2 1  4

4 1  2

7.   

0.5 5

1 10

8.   

1.   

2.   

1  3 4 5.    1 6  2

6.   

5 8

0.3 1.2

10 16

1 4

B Find the missing term in each of the following proportions. Set up each problem like the examples in this section. Write your answers as fractions in lowest terms. [Examples 3–7] 2 5

4 x

10.   

3 8

9 x

11.   

15.   

5 9

x 2

16.   

3 7

x 3

1 1   2 3 21.    y 12

2 1   3 3 22.    y 5

9.   

1 y

5 12

12.   

2 y

6 10

13.   

3 8

14.   

17.   

3 7

3 x

18.   

2 9

2 x

19.   7

x 2

20.   10

1  4 n 23.    1 12  2

3  5 n 24.    3 10  8

25.   

x 4

10 20

x 5

7 10

x 3

20 n

8 4

4 n

26.   

302 x 10

Chapter 4 Ratio and Proportion 10 2

27.   

x 12

y 12

12 48

28.   

29.   9

0.01 0.1

n 10

280 530

112 x

39.   

n 47

1,003 799

43.   

0.3 0.18

n 0.6

34.   

37.   

168 324

56 x

38.   

n 39

533 507

42.   

33.   

41.   

y 16

30.   0.75

0.4 1.2

1 x

5 0.5

31.   

0.5 x

1.4 0.7

36.   

429 y

858 130

40.   

756 903

x 129

44.   

35.   

0.3 x

2.4 0.8

573 y

2,292 316

321 1,128

x 376

Getting Ready for the Next Section Divide.

45. 360  18

46. 2,700  6

Multiply.

47. 3.5(85)

48. 4.75(105)

Solve each equation. x 10

270 6

49.   

x 45

8 18

50.   

x 25

4 20

51.   

x 3.5

85 1

52.   

Maintaining Your Skills Give the place value of the 5 in each number.

53. 250.14

54. 2.5014

Add or subtract as indicated.

55. 2.3  0.18  24.036

56. 5  0.03  1.9

57. 3.18  2.79

20 x

32.   

58. 3.4  1.975

Applications of Proportions Proportions can be used to solve a variety of word problems. The examples that follow show some of these word problems. In each case we will translate the word problem into a proportion and then solve the proportion using the method

4.5 Objectives A Use proportions to solve application problems.

developed in this chapter.

A Applications EXAMPLE 1

Examples now playing at

MathTV.com/books A woman drives her car 270 miles in 6 hours. If she con-

tinues at the same rate, how far will she travel in 10 hours?

SOLUTION

PRACTICE PROBLEMS

We let x represent the distance traveled in 10 hours. Using x, we

translate the problem into the following proportion:

Miles 8n x 270 m8 Miles     Hours 8n 10 6 m8 Hours Notice that the two ratios in the propor-

6 hours 270 miles

1. A man drives his car 288 miles in 6 hours. If he continues at the same rate, how far will he travel in: a. 10 hours b. 11 hours

tion compare the same quantities. That is, both ratios compare miles to hours. In words this proportion says:

10 hours ? miles

x miles is to 10 hours as 270 miles is to 6 hours g g g 270 x    6 10 Next, we solve the proportion. x  6  10  270 x  6  2,700 x 6 2,700     6 6  x  450 miles If the woman continues at the same rate, she will travel 450 miles in 10 hours.

EXAMPLE 2

A baseball player gets 8 hits in the first 18 games of the

season. If he continues at the same rate, how many hits will he get in 45 games?

SOLUTION

We let x represent the number of hits he will get in 45 games. Then x is to 45 as 8 is to 18 g g g Hits 8n x 8 m8 Hits    Games 8n 45 18 m8 Games

2. A softball player gets 10 hits in the first 18 games of the season. If she continues at the same rate, how many hits will she get in: a. 54 games b. 27 games

Notice again that the two ratios are comparing the same quantities, hits to games. We solve the proportion as follows: 18x  360

45  8  360

 1 8x 360    18 18 

Divide both sides by 18

x  20

360  18  20

If he continues to hit at the rate of 8 hits in 18 games, he will get 20 hits in 45 games.

4.5 Applications of Proportions

Answers 1. a. 480 miles b. 528 miles 2. a. 30 hits b. 15 hits

303

304

3. A solution contains 8 milliliters of alcohol and 20 milliliters of water. If another solution is to have the same ratio of milliliters of alcohol to milliliters of water and must contain 35 milliliters of water, how much alcohol should it contain?

Chapter 4 Ratio and Proportion

EXAMPLE 3

A solution contains 4 milliliters of alcohol and 20 milli-

liters of water. If another solution is to have the same ratio of milliliters of alcohol to milliliters of water and must contain 25 milliliters of water, how much alcohol should it contain?

SOLUTION We let x represent the number of milliliters of alcohol in the second solution. The problem translates to x milliliters is to 258 milliliters as 4 milliliters is to 20 milliliters 888n

88

8888

8n

8888

m88

Alcohol 8n x 4 m8 Alcohol    Water 8n 25 20 m8 Water 20x  100 20x  100    2 20  0

25  4  100 Divide both sides by 20

x  5 milliliters of alcohol

4. The scale on a map indicates that 1 inch on the map corresponds to an actual distance of 105 miles. Two cities are 4.75 inches apart on the map. What is the actual distance between the two cities?

EXAMPLE 4

100  20  5

The scale on a map indicates that 1 inch on the map cor-

responds to an actual distance of 85 miles. Two cities are 3.5 inches apart on the map. What is the actual distance between the two cities?

N E

W S

Eden

Avon

STATE

Liberty

158 STATE

69

Huntsville

Scale: 1 inch = 85 miles

SOLUTION We let x represent the actual distance between the two cities. The proportion is

Miles 8n x 85 m8 Miles    Inches 8n 3.5 1 m8 Inches x  1  3.5(85) x  297.5 miles

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Give an example, not found in the book, of a proportion problem you may encounter. 2 4 2. Write a word problem for the proportion   . 5 x 3. What does it mean to translate a word problem into a proportion? Answers 3. 14 mL 4. 498.75 mi

4. Name some jobs that may frequently require solving proportion problems.

4.5 Problem Set

305

Problem Set 4.5 A Solve each of the following word problems by translating the statement into a proportion. Be sure to show the proportion used in each case. [Examples 1–4]

1. Distance A woman drives her car 235 miles in 5 hours. At this rate how far will she travel in 7 hours?

3. Basketball A basketball player scores 162 points in 9

2. Distance An airplane flies 1,260 miles in 3 hours. How far will it fly in 5 hours?

4. Football In the first 4 games of the season, a football

games. At this rate how many points will he score in 20

team scores a total of 68 points. At this rate how many

games?

points will the team score in 11 games?

5. Mixture A solution contains 8 pints of antifreeze and 5

6. Nutrition If 10 ounces of a certain breakfast cereal con-

pints of water. How many pints of water must be added

tain 3 ounces of sugar, how many ounces of sugar do

to 24 pints of antifreeze to get a solution with the same

25 ounces of the same cereal contain?

concentration?

7. Map Reading The scale on a map indicates that 1 inch

8. Map Reading A map is drawn so that every 2.5 inches

corresponds to an actual distance of 95 miles. Two

on the map corresponds to an actual distance of 100

cities are 4.5 inches apart on the map. What is the

miles. If the actual distance between two cities is 350

actual distance between the two cities?

miles, how far apart are they on the map?

9. Farming A farmer knows that of every 50 eggs his

10. Manufacturing Of every 17 parts manufactured by a cer-

chickens lay, only 45 will be marketable. If his chickens

tain machine, only 1 will be defective. How many parts

lay 1,000 eggs in a week, how many of them will be

were manufactured by the machine if 8 defective parts

marketable?

were found?

11. Nursing A patient is given a prescription of 10 pills. The

12. Nursing A child is given a prescription for 9 mg of a

total prescription contains 355 milligrams. How many

drug. If she has to take 3 chewable tablets, what is the

milligrams is contained in each pill?

strength of each tablet?

13. Nursing An oral medication has a dosage strength of

14. Nursing An atropine sulfate injection has a dosage

275 mg/5 mL. If a patient takes a dosage of 300 mg,

strength of 0.1 mg/mL. If 4.5 mL was given to the

how many milliliters does he take? Round to the near-

patient, how many milligrams did she receive?

est tenth

306

Chapter 4 Ratio and Proportion

15. Nursing A tablet has a strength of 45 mg. If a patient is

16. Nursing A tablet has a dosage strength of 35 mg. What

prescribed a dose of 112.5 mg, how many tablets does

was the prescribed dosage if the patient was told to

he take?

take 1.5 tablets?

Model Trains The size of a model train relative to an actual train is referred to as its scale. Each scale is associated with a 1 ratio as shown in the table. For example, an HO model train has a ratio of 1 to 87, meaning it is  as large as an actual 87 train. 17. Length of a Boxcar How long is an actual boxcar that has an HO Scale

divide by 12 to give the answer in feet.

LGB #1 O S HO TT

18. Length of a Flatcar How long is an actual flatcar that has an LGB scale model 24 inches long? Give your answer in feet.

19. Travel Expenses A traveling salesman figures it costs

Ratio 1 1 1 1 1 1

to to to to to to

22.5 32 43.5 64 87 120

Spencer Grant/PhotoEdit

scale model 5 inches long? Give your answer in inches, then

20. Travel Expenses A family plans to drive their car during

55¢ for every mile he drives his car. How much does it

their annual vacation. The car can go 350 miles on a

cost him a week to drive his car if he travels 570 miles

tank of gas, which is 18 gallons of gas. The vacation

a week?

they have planned will cover 1,785 miles. How many gallons of gas will that take?

21. Nutrition A 9-ounce serving of pasta contains 159 grams of carbohydrates. How many grams of

22. Nutrition If 100 grams of ice cream contains 13 grams of fat, how much fat is in 250 grams of ice cream?

carbohydrates do 15 ounces of this pasta contain?

23. Travel Expenses If a car travels 378.9 miles on 50 liters

24. Nutrition If 125 grams of peas contain 26 grams of

of gas, how many liters of gas will it take to go 692

carbohydrates, how many grams of carbohydrates do

miles if the car travels at the same rate? (Round to the

375 grams of peas contain?

nearest tenth.)

25. Elections During a recent election, 47 of every 100 reg-

26. Map Reading The scale on a map is drawn so that 4.5

istered voters in a certain city voted. If there were

inches corresponds to an actual distance of 250 miles.

127,900 registered voters in that city, how many people

If two cities are 7.25 inches apart on the map, how

voted?

many miles apart are they? (Round to the nearest tenth.)

4.5 Problem Set 27. Students to Teachers The chart shows the student to

307

28. Skyscrapers The chart shows the heights of the three

teacher ratio in the United States from 1975 to 2002. If

tallest buildings in the world. The ratio of feet to meters

a school had 1,400 students in 1985, how many teach-

is given by 3.28/1. Using this information, convert the

ers does the school have? Round to the nearest

height of the Petronas Towers to meters. Round to the

teacher.

nearest hundredth.

Student Per Teacher Ratio In the U.S. 1975

Such Great Heights

20.4

1985

17.9

1995

Petronas Tower 1 & 2 Kuala Lumpur, Malaysia

Taipei 101 Taipei, Taiwan

1,483 ft Sears Tower Chicago, USA

1,670 ft

17.8

2002

1,450 ft

16.2

Source: nces.ed.gov Source: www.tenmojo.com

29. Google Earth The Google Earth image shows the

30. Google Earth The Google Earth image shows Disney

western side of The Mall in Washington, D.C. If the

World in Florida. A scale indicates that one inch is 200

scale indicates that one inch is 800 meters and the

meters. If the distance between Splash Mountain and

distance between the Lincoln Memorial and the World

the Jungle Cruise is 190 meters, what is the distance on

War II memorial is

17  16

inches, what is the actual

the map in inches?

distance between the two landmarks?

Splash Mountain Lincoln Memorial

WWII Memorial

Jungle Cruise Washington Monument

Pirates of the Caribbean

Nursing Liquid medication is usually given in milligrams per milliliter. Use the information to find the amount a patient should take for a prescribe dosage.

31. A patient is prescribed a dosage of Ceclor® of 561 mg.

32. A brand of amoxicillin has a dosage strength of 125

The dosage strength is 187 mg per 5 mL. How many

mg/5 mL. If a patient is prescribed a dosage of 25 mg,

milliliters should he take?

how many milliliters should she take?

Nursing For children, the amount of medicine prescribed is often determined by the child’s mass. Usually it is calculated from the milligrams per kilogram per day listed on the medication’s box.

33. How much should an 18 kg child be given a day if the dosage is 50 mg/kg/day?

34. How much should a 16.5 kg child be given a day if the dosage is 24 mg/kg/day?

308

Chapter 4 Ratio and Proportion

Getting Ready for the Next Section Simplify. 320 160

35. 

36. 21  105

37. 2,205  15

48 24

38. 

Solve each equation. x 5

28 7

39.   

x 4

6 3

40.   

x 21

105 15

41.   

b 15

42.   2

Maintaining Your Skills The problems below are a review of some of the concepts we covered previously. Find the following products. (Multiply.)

43. 2.7  0.5

44. (0.7)2

45. 3.18  1.2

46. (0.3)4

49. 24  0.15

50. 6.99  2.33

Find the following quotients. (Divide.)

47. 2.8  0.7

48. 0.042  0.21

Divide and round answers to the nearest hundredth.

51. 5,679  30.9

52. 4,070  64.2

Similar Figures This 8-foot-high bronze sculpture “Cellarman” in Napa, California, is an exact replica of the smaller, 12-inch sculpture. Both pieces are the product of artist Tim

Objectives A Use proportions to find the lengths of sides of similar triangles.

B

Use proportions to find the lengths of sides of other similar figures.

C

Draw a figure similar to a given figure, given the length of one side.

D

Use similar figures to solve application problems.

Courtesy of Timothy Lloyd Sculpture

Lloyd of Arroyo Grande, California.

4.6

Examples now playing at

MathTV.com/books

In mathematics, when two or more objects have the same shape, but are different sizes, we say they are similar. If two figures are similar, then their corresponding sides are proportional. In order to give more details on what we mean by corresponding sides of similar figures, it will be helpful to introduce a simple way to label the parts of a triangle.

A Similar Triangles

LABELING TRIANGLES

Two triangles that have the same shape are similar when their corresponding sides are proportional, or have the same ratio. The triangles below are similar.

c

a

f

One way to label the important parts of a triangle is to label the vertices with capital letters and the sides with lower-case letters.

B

d

a

c e

A

b Corresponding Sides

Ratio

side a corresponds with side d

a  d

side b corresponds with side e

b  e

side c corresponds with side f

c  f

b

C

Notice that side a is opposite vertex A, side b is opposite vertex B, and side c is opposite vertex C. Also, because each vertex is the vertex of one of the angles of the triangle, we refer to the three interior angles as A, B, and C.

Because their corresponding sides are proportional, we write b c a      e f d

4.6 Similar Figures

309

310

Chapter 4 Ratio and Proportion

PRACTICE PROBLEMS

EXAMPLE 1

The two triangles below are similar. Find side x.

1. The two triangles below are similar. Find the missing side, x.

24

x 25

10 14

6

5 x

28

SOLUTION

7

To find the length x, we set up a proportion of equal ratios. The ratio

of x to 5 is equal to the ratio of 24 to 6 and to the ratio of 28 to 7. Algebraically we have 24 x     6 5

28 x     7 5

and

We can solve either proportion to get our answer. The first gives us x   4 5 x45 x  20

24   4 6 Multiply both sides by 5 Simplify

B Other Similar Figures When one shape or figure is either a reduced or enlarged copy of the same shape or figure, we consider them similar. For example, video viewed over the Internet was once confined to a small “postage stamp” size. Now it is common to see larger video over the Internet. Although the width and height have increased, the shape of the video has not changed.

video clip proportional to those in Example 2 with a width of 360 pixels.

Note

A pixel is the smallest dot made on a computer monitor. Many computer monitors have a width of 800 pixels and a height of 600 pixels.

EXAMPLE 2

The width and height of the two video clips are propor-

tional. Find the height, h, in pixels of the larger video window. Image: BigStockPhoto.com © Devanne Philippe

2. Find the height, h, in pixels of a

Music Video Music Video

h

120



+ –

160

+

320

SOLUTION We write our proportion as the ratio of the height of the new video to the height of the old video is equal to the ratio of the width of the new video to the width of the old video: 320 h    160 120 h   2 120 Answers 1. 35 2. 270

h  2  120 h  240 The height of the larger video is 240 pixels.

311

4.6 Similar Figures

C Drawing Similar Figures EXAMPLE 3

Draw a triangle similar to triangle ABC, if AC is propor-

3. Draw a triangle similar to triangle ABC, if AC is proportional to GI.

tional to DF. Make E the third vertex of the new triangle.

B

A

C

D

G

F

I

SOLUTION We see that AC is 3 units in length and BC has a length of 4 units. Since AC is proportional to DF, which has a length of 6 units, we set up a proportion to find the length EF. EF DF    AC BC EF 6     4 3 EF   2 4 EF  8 Now we can draw EF with a length of 8 units, then complete the triangle by drawing line DE.

E

D

E

F

D

F

We have drawn triangle DEF similar to triangle ABC.

D Applications EXAMPLE 4

A building casts a shadow of 105 feet while a 21-foot flag-

pole casts a shadow that is 15 feet. Find the height of the building.

21 ft

105 ft

4. A building casts a shadow of 42 feet, while an 18-foot flagpole casts a shadow that is 12 feet. Find the height of the building.

Answer 3. See solutions section. 15 ft

312

Chapter 4 Ratio and Proportion

SOLUTION The figure shows both the building and the flagpole, along with their respective shadows. From the figure it is apparent that we have two similar triangles. Letting x  the height of the building, we have 105 x     21 15 15x  2205 x  147

Extremes/means property Divide both sides by 15

The height of the building is 147 feet.

The Violin Family

The instruments in the violin family include the bass, cello, vi-

ola, and violin. These instruments can be considered similar figures because the

Note

These numbers are whole number approximations used to simplify our calculations. 5. Find the body length of an instrument proportional to the violin family that has a total length of 32 inches.

Royalty-Free/Corbis

entire length of each instrument is proportional to its body length.

EXAMPLE 5

The entire length of a violin is 24 inches, while the body

length is 15 inches. Find the body length of a cello if the entire length is 48 inches.

SOLUTION Let b equal the body length of the cello, and set up the proportion. 48 b    24 15 b   2 15 b  2  15 b  30 The body length of a cello is 30 inches.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. What are similar figures? 2. How do we know if corresponding sides of two triangles are proportional? 3. When labeling a triangle ABC, how do we label the sides? 4. How are proportions used when working with similar figures?

Answers 4. 63 ft 5. 20 in.

4.6 Problem Set

Problem Set 4.6 A In problems 1–4, for each pair of similar triangles, set up a proportion in order to find the unknown. [Example 1] 1.

2.

18 6

h

15

10

4 h

6

3.

4.

y

4

12 8

15

y

10

21

B In problems 5–10, for each pair of similar figures, set up a proportion in order to find the unknown. [Example 2] 5.

6.

16

x

x

9

12

40

9

24

7.

8.

15

5

3 a

48 a

54

36

10.

9.

42 40 50

y 40

30

28 y

313

314

Chapter 4 Ratio and Proportion

C For each problem, draw a figure on the grid on the right that is similar to the given figure. [Example 3] 11. AC is proportional to DF.

12. AB is proportional to DE.

A

B

D

B

E

C A

C

D

F

13. BC is proportional to EF.

14. AC is proportional to DF.

A E B

F B

C

D F

C A 15. DC is proportional to HG.

A

16. AD is proportional to EH.

B H

D

C

17. AB is proportional to FG.

G

A

D

B

C

E

H

18. BC is proportional to FG.

B

C B

D

A

E

G

A

F

D

F

C

G

4.6 Problem Set

D

Applying the Concepts

315

[Examples 4, 5]

19. Length of a Bass The entire length of a violin is 24

20. Length of an Instrument The entire length of a violin is

inches, while its body length is 15 inches. The bass is

24 inches, while the body length is 15 inches. Another

an instrument proportional to the violin. If the total

instrument proportional to the violin has a body length

length of a bass is 72 inches, find its body length.

of 25 inches. What is the total length of this instrument?

15 in.

x 24 in.

15 in.

24 in.

72 in.

24 in.

21. Video Resolution A new graphics card can increase the

22. Screen Resolution The display of a 20 computer monitor

resolution of a computer’s monitor. Suppose a monitor

is proportional to that of a 23 monitor. A 20 monitor

has a horizontal resolution of 800 pixels and a vertical

has a horizontal resolution of 1,680 pixels and a verti-

resolution of 600 pixels. By adding a new graphics card,

cal resolution of 1,050 pixels. If a 23 monitor has a

the resolutions remain in the same proportions, but the

horizontal resolution of 1,920 pixels, what is its vertical

horizontal resolution increases to 1,280 pixels. What is

resolution?

the new vertical resolution?

1920 1680

1050

23. Screen Resolution The display of a 20 computer

x

24. Video Resolution A new graphics card can increase the

monitor is proportional to that of a 17 monitor. A 20

resolution of a computer’s monitor. Suppose a monitor

monitor has a horizontal resolution of 1,680 pixels and

has a horizontal resolution of 640 pixels and a vertical

a vertical resolution of 1,050 pixels. If a 17 monitor

resolution of 480 pixels. By adding a new graphics card,

has a vertical resolution of 900 pixels, what is its

the resolutions remain in the same proportions, but the

horizontal resolution?

vertical resolution increases to 786 pixels. What is the new horizontal resolution?

25. Height of a Tree A tree casts a shadow 38 feet long,

26. Height of a Building A building casts a shadow 128 feet

while a 6-foot man casts a shadow 4 feet long. How tall

long, while a 24-foot flagpole casts a shadow 32 feet

is the tree?

long. How tall is the building?

24 ft

6 ft 38 ft

4 ft

128 ft

32 ft

316

Chapter 4 Ratio and Proportion

27. Eiffel Tower At the Paris Las Vegas Hotel is a replica of

28. Pyramids The Luxor Hotel in Las Vegas is almost an ex-

the Eiffel Tower in France. The heights of the tower in

act model of the pyramid of Khafre, the second largest

Las Vegas and the tower in France are 460 feet and

Egyptian pyramid. The heights of the Luxor hotel and

1,063 feet respectively. The base of the Eiffel Tower in

the pyramid of Khafre are 350 feet and 470 feet respec-

France is 410 feet wide. What is the width of the base

tively. If the base of the pyramid in Khafre was 705 feet

of the tower in Las Vegas? Round to the nearest foot.

wide, what is the width of the base of the Luxor Hotel?

Maintaining Your Skills The problems below are a review of the four basic operations with fractions and decimals. Add. 3 4

29. 2.03  11.958  0.002

1 6

5 8

30.     

Subtract.

31. 65.002  24.003

1 8

5 8

1 7

1 3

32. 5  2

Multiply.

33. 42.18  0.0025

34. 7  2

Divide.

3 4

35. 378.9  21.05

36. 12.25   2 3

1 2

2 3

37. Find the sum of 2 and 1. 2 3

1 2

38. Find the difference of 2 and 1. 1 2

39. Find the product of 2 and 1.

2 3

1 2

40. Find the quotient of 2 and 1.

Extending the Concepts 41. The rectangles shown here are similar, with similar rectangles within.

a. In the smaller figure, what is the ratio of the shaded to nonshaded rectangles?

b. Shade the larger rectangle such that the ratio of shaded to nonshaded 1

rectangles is 2.

c. For each of the figures, what is the ratio of the shaded rectangles to total rectangles?

Chapter 4 Summary Ratio [4.1] EXAMPLES a The ratio of a to b is . The ratio of two numbers is a way of comparing them b using fraction notation.

1. The ratio of 6 to 8 is 6  8 which can be reduced to 3  4

Rates [4.2] Whenever a ratio compares two quantities that have different units (and neither

2. If a car travels 150 miles in 3 hours, then the ratio of miles to

unit can be converted to the other), then the ratio is called a rate.

hours is considered a rate: 150 miles miles   50  3 hours hour  50 miles per hour

Unit Pricing [4.2] The unit price of an item is the ratio of price to quantity when the quantity is one unit.

3. If a 10-ounce package of frozen peas costs 69¢, then the price per ounce, or unit price, is 69 cents cents   6.9  10 ounces ounce  6.9 cents per ounce

Solving Equations by Division [4.3] Dividing both sides of an equation by the same number will not change the solution to the equation. For example, the equation 5  x  40 can be solved by dividing both sides by 5.

4. Solve: 5  x  40 5  x  40 5 x 40     5  5 x8

Divide both sides by 5 40  5  8

Proportion [4.4] 5. The following is a proportion:

A proportion is an equation that indicates that two ratios are equal. The numbers in a proportion are called terms and are numbered as follows:

6 3     8 4

First term 88n a c m88 Third term Second term 88n b  d m88 Fourth term The first and fourth terms are called the extremes. The second and third terms are called the means. a c    d m888 Extremes

Means 888n b

Chapter 4

Summary

317

318

Chapter 4 Ratio and Proportion

Fundamental Property of Proportions [4.4] In any proportion the product of the extremes is equal to the product of the means. In symbols, If

a c    b d

then

ad  bc

Finding an Unknown Term in a Proportion [4.4] 6. Find x: 2  8 5

To find the unknown term in a proportion, we apply the fundamental property of

x

2x58

proportions and solve the equation that results by dividing both sides by the

2  x  40 2 x 40     2 2  x  20

number that is multiplied by the unknown. For instance, if we want to find the unknown in the proportion 2 8    5 x we use the fundamental property of proportions to set the product of the extremes equal to the product of the means.

Using Proportions to Find Unknown Length with Similar Figures [4.6] 7. Find x.

Two triangles that have the same shape are similar when their corresponding sides are proportional, or have the same ratio. The triangles below are similar.

6

4 x

c

f

a

d

6

4 6    6 x

e b

36  4x 9x

Corresponding Sides

Ratio a  d

side a corresponds with side d side b corresponds with side e

b  e

side c corresponds with side f

c  f

Because their corresponding sides are proportional, we write b c a      e f d

COMMON MISTAKES A common mistake when working with ratios is to write the numbers in the wrong order when writing the ratio as a fraction. For example, the ratio 3 to 3

5

5 is equivalent to the fraction 5. It cannot be written as 3.

Chapter 4

Review

Write each of the following ratios as a fraction in lowest terms. [4.1]

1. 9 to 30

1 3

2. 30 to 9

2 3

3 4

5. 2 to 1

1 5

6. 3 to 2

3 5

2 7

3 7

4 7

8 5

8 9

3.  to 

4.  to 

7. 0.6 to 1.2

8. 0.03 to 0.24

3 7

10.  to 

9.  to 

The chart shows where each dollar spent on gasoline in the United States goes. Use the chart for problems 11–14. [4.1]

11. Ratio Find the ratio of money paid for taxes to money that goes to oil company profits. Producing country 49¢ Oil company profits 4¢ Local station 13¢ Oil company costs 16¢

12. Ratio What is the ratio of the number of cents spent on

Taxes 18¢

oil company costs to the number of cents that goes to local stations?

13. Ratio Give the ratio of oil company profits to oil company costs.

14. Ratio Give the ratio of taxes to oil company costs and profits.

15. Gas Mileage A car travels 285 miles on 15 gallons of

16. Speed of Sound If it takes 2.5 seconds for sound to

gas. What is the rate of gas mileage in miles per gallon?

travel 2,750 feet, what is the speed of sound in feet per

[4.2]

second? [4.2]

17. Unit Price A certain brand of ice cream comes in two

18. Unit Price A 6-pack of store-brand soda is $1.25, while

different-sized cartons with prices marked as shown.

a 24-pack of name-brand soda is $5.99. Find the price

Give the unit price for each carton, and indicate which

per soda for each, and determine which is less

is the better buy.

expensive.

8 oz 8 oz

64-ounce carton

32-ounce carton

$5.79

$2.69

8 oz 8 oz

8 oz 8 oz

Chapter 4

Review

319

320

Chapter 4 Ratio and Proportion

Find the missing term in each of the following proportions. [4.4] n 18 20.    18 54

5 35 19.    7 x

23. Chemistry Suppose every 2,000 milliliters of a solution

1  2 y 21.    10 2

x 1.8

5 1.5

22.   

1

24. Nutrition If 2 cup of breakfast cereal contains 8 mil1

contains 24 milliliters of a certain drug. How many mil-

ligrams of calcium, how much calcium does 12 cups of

liliters of solution are required to obtain 18 milliliters of

the cereal contain? [4.5]

the drug? [4.5]

25. Weight Loss A man loses 8 pounds during the first

26. Men and Women If the ratio of men to women in a math

2 weeks of a diet. If he continues losing weight at the

class is 2 to 3, and there are 12 men in the class, how

same rate, how long will it take him to lose 20 pounds?

many women are in the class? [4.5]

[4.5]

27. Nursing A patient received a dosage of 7.5 mg of a

28. Nursing A patient is told to take 300 mg of a certain

certain medication. How many tablets must he take if

medication daily. If he takes it in two sittings, how

the tablet strength is 2.5 mg?

many milligrams is he taking each time he takes the medication?

29. Similar Triangles The triangles below are similar figures.

30. Find x if the two rectangles are similar.

Find x. [4.6]

x 12 cm

8 cm 8

10 cm

6 x

12

31. Video Size The width and height of the two video clips are proportional. Find the height, h, in pixels of the larger video

Image: BigStockPhoto.com © Devanne Philippe

window. Music Video Music Video

h

120



+ –

180 240

+

Chapter 4

Cumulative Review

Simplify.

1.

8359

378 21

2. 3011  1032

3. 

4. (3  8)  2

6. 53

7. 6  23  1

8. 135  15

401 1762

5. 311 5 ,6 8 9 

76 4

9. 56  18

13. 83.6  12.12

4 1

17. 5  

2 5

10. 

11. (11  2)  (403  102)

12. (3.6)(7.1)

14. 6.4  3.12  5.07

15. 30.6  6.8

16. 

1 6

2



2 9

18.   

1 5

21. (1.3)  (2.1)

 3  2 1

2 3

2

1

3

1 4



20. 12  5

19. 5  14  1

22. 3100   81 

Solve. x 20

5 4

9 10

18 x

23.   

24.   

25. Find the perimeter and area of the figure below.

26. Find the perimeter of the figure below.

20 cm

2 2

5 cm

11 in.

4 in. 6 in.

13 cm 5 cm 10 cm

3 in. 4 in.

Chapter 4

Cumulative Review

321

322

Chapter 4 Ratio and Proportion

27. Construction A corrugated steel pipe has a radius of 3

28. Find x if the two rectangles are similar.

feet and length of 20 feet.

x 12 cm

20 ft

9 cm

3 ft

12 cm

a. Find the circumference of the pipe. Use 3.14 for π. b. Find the volume of the pipe. Use 3.14 for π.

29. Ratio If the ratio of men to women in a self-defense

30. Surfboard Length A surfing company decides that a

class is 3 to 4, and there are 15 men in the class, how

surfboard would be more efficient if its length were

many women are in the class?

reduced by 38 inches. If the original length was 7 feet

5

3  16

inches, what will be the new length of the board (in

inches)?

31. Average Distance A bicyclist on a cross-country trip

32. Teaching A teacher lectures on five sections in two

travels 72 miles the first day, 113 miles the second day,

class periods. If she continues at the same rate, on

108 miles the third day, and 95 miles the fourth day.

how many sections can the teacher lecture in 60 class

What is her average distance traveled during the four

periods?

days?

33. Unit Price A certain

34. Model Plane This

brand of ice cream

plane is from the

comes in two different-

Franklin Mint. It is

sized cartons with

scale model of a 4 8

prices marked as

the F4U Corsair,

price for each carton, and indicate which is the better buy.

72-ounce carton

48-ounce carton

$6.10

$3.56

the last propellerdriven fighter plane

Franklin Mint

shown. Give the unit

1

built by the United States. If the wingspan of the model is 10.25 inches, what is the wingspan of the actual plane? Give your answer in inches, then divide by 12 to give the answer in feet.

Chapter 4

Test

Write each ratio as a fraction in lowest terms. 3 4

1 3

3. 5 to 3

3 11

5 6

2.  to 

1. 24 to 18

4. 0.18 to 0.6

5 11

5.  to 

A family of three budgeted the following amounts for some of their monthly bills:

Family Budget

6. Ratio Find the ratio of house payment to fuel payment. Fuel payment $125 Phone payment $60 House payment $600

7. Ratio Find the ratio of phone payment to food payment.

Food payment $250

8. Gas Mileage A car travels 414 miles on 18 gallons of gas. What is the rate of gas mileage in miles per gallon?

9. Unit Price A certain brand of frozen orange juice comes in two different-sized cans with prices marked as shown. Give the unit price for each can, and indicate which is the better buy. Frozen

Orange Juice ORIGINAL

16-ounce can

$2.59

16 oz.

Frozen

Orange Juice ORIGINAL

12-ounce can

$1.89

12 oz.

Chapter 4

Test

323

324

Chapter 4 Ratio and Proportion

Find the unknown term in each proportion. 5 6

30 x

1.8 6

2.4 x

10.   

11.   

12. Baseball A baseball player gets 9 hits in his first

13. Map Reading The scale on a map indicates that 1 inch

21 games of the season. If he continues at the same

on the map corresponds to an actual distance of

rate, how many hits will he get in 56 games?

60 miles. Two cities are 24 inches apart on the map.

1

14. Model Trains Earlier we indicated that the size of a model train relative to an actual train is referred to as its scale. Each scale is associated with a ratio as shown in the table below. For example, an HO model train has a ratio of 1 to 87, meaning it is

1  87

as large

as an actual train.

Scale

Ratio

LGB #1 O S HO TT

1 1 1 1 1 1

to to to to to to

22.5 32 43.5 64 87 120

a. If all six scales model the same boxcar, which one will have

Barry Rosenthal/Getty Images

What is the actual distance between the two cities?

the largest model boxcar?

b. How many times larger is a boxcar that is O scale than a boxcar that is HO scale?

15. The triangles below are similar figures. Find h.

16. Video Size The width and height of the two video clips are proportional. Find the height, h, in pixels of the

20

h

15

12

Image: BigStockPhoto.com © Devanne Philippe

larger video window. Music Video Music Video

h

120



+ –

160 400

Nursing Sometimes body surface area is used to calculate the necessary dosage for a patient. 17. The dosage for a drug is 15 mg/m2. If an adult has a BSA of 1.8 m , what dosage should he take? 2

18. Find the dosage an adult should take if her BSA is 1.3 m2 and the dosage strength is 25.5 mg/m2.

+

Chapter 4 Projects RATIO AND PROPORTION

GROUP PROJECT Soil Texture Number of People Time Needed Equipment Background

2–3 8–12 minutes Paper and pencil

Sand

Soil texture is defined as the relative proportions of sand, silt, and clay. The figure shows

Silt Clay

the relative sizes of each of these soil particles. People who study soil science, or work with

Procedure

soil, become very familiar with ratios.

FIGURE 1 Relative sizes of sand, silt, and clay

A certain type of soil is one part silt, two parts

4. What is the sum of the three fractions given

clay, and three parts sand. Use your under-

in questions 1–3?

standing of ratios and proportions to find the

5. Let the 48 parts of the rectangle below each

following ratios. Write these ratios as fractions.

represent one cubic yard of the soil mixture

1. Sand to total soil

above. Label each of the squares with either

2. Silt to total soil

S (for sand), C (for clay), or T (for silt) based

3. Clay to total soil

on the amount of each in 48 cubic yards of this soil.

Chapter 4

Projects

325

RESEARCH PROJECT The Golden Ratio If you were going to design something with a rectangular shape—a television screen, a pool, or a house, for example—would one shape be

Kevin Schafer/Corbis

more pleasing to the eye than another?

For many people, the most pleasing rectan-

Research the golden ratio in mathematics

gles are rectangles in which the ratio of length

and give examples of where it is used in archi-

to width is a number called the golden ratio,

tecture and art. Then measure the length and

which we have written below.

width of some rectangles around you (TV/

1 5 Golden Ratio   1.6180339 . . . 2

computer monitor screen, picture frame, math book, calculator, a dollar, notebook paper, etc.). Calculate the ratio of length to width and indicate which are close to the golden ratio.

326

Chapter 4 Ratio and Proportion

A Glimpse of Algebra In “A Glimpse of Algebra” in Chapter 3, we spent some time adding polynomials. Now we can use the formula for the area of a rectangle developed in Chapter 1, A  l w, to multiply some polynomials. Suppose we have a rectangle with length x  3 and width x  2. Remember, the letter x is used to represent a number, so x  3 and x  2 are just numbers. Here is a diagram:

x

3

x

2

The area of the whole rectangle is the length times the width, or Total area  (x  3)(x  2) But we can also find the total area by first finding the area of each smaller rectangle, and then adding these smaller areas together. The area of each rectangle is its length times its width, as shown in the following diagram:

x

3

x

x2

3x

2

2x

6

Because the total area (x  3)(x  2) must be the same as the sum of the smaller areas, we have: (x  3)(x  2)  x 2  2x  3x  6  x 2  5x  6

Add 2x and 3x to get 5x

The polynomial x 2  5x  6 is the product of the two polynomials x  3 and x  2. Here are some more examples.

PRACTICE PROBLEMS

EXAMPLE 1

Find the product of x  5 and x  2 by using the following

1. Find the product of x  4 and x  2 by using the following diagram:

diagram:

x

5

x

x

x

2

2

A Glimpse of Algebra

4

327

328

Chapter 4 Ratio and Proportion

SOLUTION

The total area is given by (x  5)(x  2). We can fill in the smaller

areas by multiplying length times width in each case:

x

5

x

x2

5x

2

2x

10

The product of (x  5) and (x  2) is (x  5)(x  2)  x 2  2x  5x  10  x 2  7x  10

2. Find the product of 3x  7 and 2x  5 by using the following diagram:

3x

EXAMPLE 2

Find the product of 2x  5 and 3x  2 by using the follow-

ing diagram:

2x

5

7

2x

3x

2

5

SOLUTION

We fill in each of the smaller rectangles by multiplying length times

width in each case:

2x

5

3x

6x 2

15x

2

4x

10

Using the information from the diagram, we have: (2x  5)(3x  2)  6x 2  4x  15x  10  6x 2  19x  10

Answers 1. x 2  6x  8 2. 6x 2  29x  35

A Glimpse of Algebra Problems

A Glimpse of Algebra Problems Use the diagram in each problem to help multiply the polynomials.

1. (x  4)(x  2)

2. (x  1)(x  3)

x

4

x

x

1

x

2 3

3. (2x  3)(3x  2)

4. (5x  4)(6x  1)

2x

4

5x

3

3x

6x

1 2

5. (7x  2)(3x  4)

6. (3x  5)(2x  5)

7x

3x

2 2x

3x

4

5

5

329

330

Chapter 4 Ratio and Proportion

Multiply each of the following pairs of polynomials. You may draw a rectangle to assist you, but you don’t have to.

7. (x  2)(x  5)

8. (x  3)(x  6)

9. (2x  3)(x  4)

10. (2x  4)(x  3)

11. (7x  3)(2x  5)

12. (5x  4)(3x  3)

13. (3x  2)(3x  2)

14. (2x  3)(2x  3)

15. (4a  5)(a  1)

16. (5a  7)(a  2)

17. (7y  8)(6y  9)

18. (9y  3)(2y  8)

19. (4  6x)(2  3x)

20. (5  3x)(2  5x)

5

Percent

Chapter Outline 5.1 Percents, Decimals, and Fractions 5.2 Basic Percent Problems 5.3 General Applications of Percent 5.4 Sales Tax and Commission 5.5 Percent Increase or Decrease and Discount 5.6 Interest 5.7 Pie Charts

Introduction The eruption of Mount St. Helens in 1980 was the most catastrophic volcanic eruption in American history. The volcano is located in the state of Washington about 100 miles south of Seattle. It’s eruption caused dozens of deaths, and destroyed almost 230 acres of forest, along with more than 200 homes. The effects on the carrying capacity of nearby rivers were devastating as well. As the rivers filled with debris and sediment, surrounding lands flooded, more vegetation was lost, and the fish population was greatly reduced.

Effects of Lava Flows on Rivers Carrying Capacity of the Cowlitz River (cubic feet per second)

Channel Depth of Columbia River

Prior to 1980

76,000

40 feet

After 1980 Eruption

15,000

14 feet

80%

65%

Percent Decrease

Source: US Forest Service

In this chapter we will work with fractions, decimals, and percents. We will see how percents are used in everyday applications, including volcanoes.

331

Chapter Pretest The pretest below contains problems that are representative of the problems you will find in the chapter. Change each percent to a decimal.

1. 68%

2. 2%

3. 21.5%

5. 0.386

6. 3.98

Change each decimal to a percent.

4. 0.39

Change each percent to a fraction or mixed number in lowest terms.

7. 33%

8. 45%

9. 8.5%

Change each fraction or mixed number to a percent. 67 100

1 4

4 5

10. 

11. 

12. 2 

13. What number is 5% of 24?

14. What percent of 40 is 6?

15. 12 is 24% of what number?

Getting Ready for Chapter 5 The problems below review material covered previously that you need to know in order to be successful in Chapter 5. If you have any difficulty with the problems here, you need to go back and review before going on to Chapter 5. Perform the indicated operations.

1. 136  5.44

2. 300  75

3. 1,793,000  315,568

1 65 4.    2 100

5. 0.2  100

6. 4.89  100

7. 0.15  63

8. 

35.2 100

9. 3.62  100

34 0.29

60 360

10.  (Round to the nearest tenth.)

11. 600  0.04  

Reduce. 36 100

12. 

45 1000

13. 

1 2

14. Change 32  to an improper fraction.

Change each fraction or mixed number to a decimal. 3 8

15. 

5 12

1 2

16. 

17. 2 

19. 0.12n  1,836

20. 1.075x  3,200 (Round to the

Solve.

18. 25  0.40  n

nearest hundredth.)

332

Chapter 5 Percent

Percents, Decimals, and Fractions Introduction . . . The sizes of categories in the pie chart below are given as percents. The whole pie chart is represented by 100%. In general, 100% of something is the whole thing. In this section we will look at the meaning of percent. To begin, we learn to change decimals to percents and percents to decimals.

5.1 Objectives A Change percents to fractions. B Change percents to decimals. C Change decimals to percents. D Change percents to fractions in lowest terms.

E

Change fractions to percents.

Factors Producing More Traffic Today Increase in trip lengths 35%

Examples now playing at

Increase in population 13%

MathTV.com/books

Fewer occupants traveling in vehicles 17% Switch to driving from other modes of transportation 17% Increase in trips taken 18%

A The Meaning of Percent Percent means “per hundred.” Writing a number as a percent is a way of comparing the number with 100. For example, the number 42% (the % symbol is read “percent”) is the same as 42 one-hundredths. That is: 42 42%   100 Percents are really fractions (or ratios) with denominator 100. Here are some examples that show the meaning of percent.

EXAMPLE 1

50 50%   100

EXAMPLE 2

75 75%   100

EXAMPLE 3

25 25%   100

EXAMPLE 4

33 33%   100

EXAMPLE 5

6 6%   100

EXAMPLE 6

160 160%   100

PRACTICE PROBLEMS Write each number as an equivalent fraction without the % symbol. 1. 40%

2. 80%

3. 15%

4. 37%

5. 8%

6. 150% Answers

5.1 Percents, Decimals, and Fractions

40 1.  100

80 2.  100

15 3.  100

37 4.  100

8 5.  100

150 6.  100

333

334

Chapter 5 Percent

B Changing Percents to Decimals To change a percent to a decimal number, we simply use the meaning of percent. 7. Change to a decimal. a. 25.2% b. 2.52%

EXAMPLE 7 SOLUTION

Change 35.2% to a decimal.

We drop the % symbol and write 35.2 over 100. 35.2 35.2%   100  0.352

Use the meaning of % to convert to a fraction with denominator 100 Divide 35.2 by 100

We see from Example 7 that 35.2% is the same as the decimal 0.352. The result is that the % symbol has been dropped and the decimal point has been moved two places to the left. Because % always means “per hundred,” we will always end up moving the decimal point two places to the left when we change percents to decimals. Because of this, we can write the following rule.

Rule To change a percent to a decimal, drop the % symbol and move the decimal point two places to the left, inserting zeros as placeholders if needed.

Here are some examples to illustrate how to use this rule. Change each percent to a decimal. 8. 40%

EXAMPLE 8

9. 80%

EXAMPLE 9

10. 15%

EXAMPLE 10

11. 5.6%

EXAMPLE 11

12. 4.86%

EXAMPLE 12

13. 0.6%

EXAMPLE 13

14. 0.58%

EXAMPLE 14

25%  0.25

75%  0.75

Notice that the results in Examples 8, 9, and 10 are consistent with the results in Examples 1, 2, and 3

50%  0.50

6.8%  0.068

Notice here that we put a 0 in front of the 6 so we can move the decimal point two places to the left

3.62%  0.0362

0.4%  0.004

This time we put two 0s in front of the 4 in order to be able to move the decimal point two places to the left

The cortisone cream shown here is 0.5% hydrocortisone.

Writing this number as a decimal, we have 0.5%  0.005

Answers 7. a. 0.252 b. 0.0252 8. 0.40 9. 0.80 10. 0.15 11. 0.056 12. 0.0486 13. 0.006 14. 0.0058

335

5.1 Percents, Decimals, and Fractions

C Changing Decimals to Percents Now we want to do the opposite of what we just did in Examples 7–14. We want to change decimals to percents. We know that 42% written as a decimal is 0.42, which means that in order to change 0.42 back to a percent, we must move the decimal point two places to the right and use the % symbol: 0.42  42%

Notice that we don’t show the new decimal point if it is at the end of the number

Rule To change a decimal to a percent, we move the decimal point two places to the right and use the % symbol.

Examples 15–20 show how we use this rule.

EXAMPLE 15 EXAMPLE 16 EXAMPLE 17

EXAMPLE 18

EXAMPLE 19

0.27  27%

Write each decimal as a percent. 15. 0.35

4.89  489%

16. 5.77

0.2  0.20  20%

Notice here that we put a 0 after the 2 so we can move the decimal point two places to the right

17. 0.4

0.09  09%  9%

Notice that we can drop the 0 at the left without changing the value of the number

18. 0.03

25  25.00  2,500% Here, we put two 0s after the 5 so

19. 45

that we can move the decimal point two places to the right

EXAMPLE 20

A softball player has a batting average of 0.650. As a per-

20. 0.69

Eyewire/Getty Images

cent, this number is 0.650  65.0%.

As you can see from the examples above, percent is just a way of comparing numbers to 100. To multiply decimals by 100, we move the decimal point two places to the right. To divide by 100, we move the decimal point two places to the left. Because of this, it is a fairly simple procedure to change percents to decimals and decimals to percents.

Answers 15. 35% 16. 577% 17. 40% 18. 3% 19. 4,500% 20. 69%

336

Chapter 5 Percent

Who Pays Health Care Bills

D Changing Percents to Fractions To change a percent to a fraction, drop the % symbol and write the original number over 100.

EXAMPLE 21

The pie chart in the margin shows who pays health care

bills. Change each percent to a fraction. Patient 19%

SOLUTION

In each case, we drop the percent symbol and write the number

over 100. Then we reduce to lowest terms if possible.

Private insurance 36%

19 19%   100

Government 45%

45 9 45%     100 20 h

36 9 36%     100 25 h

reduce

21. Change 82% to a fraction in

reduce

lowest terms.

22. Change 6.5% to a fraction in

EXAMPLE 22

Change 4.5% to a fraction in lowest terms.

lowest terms.

SOLUTION

We begin by writing 4.5 over 100: 4.5 4.5%   100

We now multiply the numerator and the denominator by 10 so the numerator will be a whole number: 4.5  10 4.5    100 100  10

Multiply the numerator and the denominator by 10

45   1,000 9   200 1

23. Change 42  2 % to a fraction in lowest terms.

Reduce to lowest terms

EXAMPLE 23 SOLUTION

1 Change 32% to a fraction in lowest terms. 2 1 Writing 32% over 100 produces a complex fraction. We change 2

1 32 to an improper fraction and simplify: 2 1 32 2 1 32  %   2 100 65  2   100

Change 322 to the improper fraction 2

1 65     2 100

 Dividing by 100 is the same as multiplying by  100

  13  1 5   2 5  20

Multiplication

13   40

Reduce to lowest terms

1

65

1

Note that we could have changed our original mixed number to a decimal first and then changed to a fraction: Answers 41 21.  50

13 22.  200

17 23.  40

1 32.5 32.5  10 325 5 5   13 13 32  %  32.5%           2 100 100  10 1000 5 5   40 40 The result is the same in both cases.

337

5.1 Percents, Decimals, and Fractions

E Changing Fractions to Percents To change a fraction to a percent, we can change the fraction to a decimal and then change the decimal to a percent.

EXAMPLE 24

Suppose the price your bookstore pays for your textbook 7 7 is  of the price you pay for your textbook. Write  as a percent. 10 10 7 SOLUTION We can change  to a decimal by dividing 7 by 10: 10

24. Change to a percent. 9 10 9 b.  20

a. 

0.7 .0  107 70  0 We then change the decimal 0.7 to a percent by moving the decimal point two places to the right and using the % symbol: 0.7  70% You may have noticed that we could have saved some time in Example 24 by 7 simply writing as an equivalent fraction with denominator 100. That is: 10 7  10 70 7       70% 10 100 10  10 7 This is a good way to convert fractions like  to percents. It works well for frac10 tions with denominators of 2, 4, 5, 10, 20, 25, and 50, because they are easy to change to fractions with denominators of 100.

EXAMPLE 25

3 Change  to a percent. 8 3 SOLUTION We write  as a decimal by dividing 3 by 8. We then change the 8 decimal to a percent by moving the decimal point two places to the right and using the % symbol. 3   0.375  37.5% 8

EXAMPLE 26 SOLUTION

5 8 9 b.  8

a. 

.375 83 .000 2 4  60 56  40 40  0

5 Change  to a percent. 12 We begin by dividing 5 by 12: .4166 .0 0  00  125

25. Change to a percent.

26. Change to a percent. 7 12 13 b.  12

a. 

4 8  20 12  80 72  80 72 

Answers 24. a. 90% b. 45% 25. a. 62.5% b. 112.5%

338

Chapter 5 Percent Because the 6s repeat indefinitely, we can use mixed number notation to write

Note

When rounding off, let’s agree to round off to the nearest thousandth and then move the decimal point. Our answers in percent form will then be accurate to the nearest tenth of a percent, as in Example 26.

5 2   0.416   41  % 12 3 Or, rounding, we can write 5   41.7% 12

To the nearest tenth of a percent

EXAMPLE 27 27. Change to a percent. a. 33 b.

4 7 3 8

SOLUTION

1 Change 2  to a percent. 2 We first change to a decimal and then to a percent: 1 2   2.5 2  250%

Table 1 lists some of the most commonly used fractions and decimals and their equivalent percents. TABLE 1

Fraction

Decimal

Percent

1  2

0.5

50%

1  4

0.25

25%

3  4

0.75

75%

1  3

 0.3

33 3%

2  3

 0.6

66 3%

1  5

0.2

20%

2  5

0.4

40%

3  5

0.6

60%

4  5

0.8

80%

1

2

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. What is the relationship between the word percent and the number 100? 2. Explain in words how you would change 25% to a decimal. 3. Explain in words how you would change 25% to a fraction. 1 4. After reading this section you know that , 0.5, and 50% are equiva2 lent. Show mathematically why this is true. Answers 26. a. 5813% 58.3% b. 10813% 108.3% 27. a. 375% b. 387.5%

5.1 Problem Set

Problem Set 5.1 A Write each percent as a fraction with denominator 100. [Examples 1–6] 1. 20%

2. 40%

7. 65%

8. 35%

3. 60%

4. 80%

5. 24%

6. 48%

B Change each percent to a decimal. [Examples 7–14] 9. 23%

10. 34%

11. 92%

12. 87%

13. 9%

14. 7%

15. 3.4%

16. 5.8%

17. 6.34%

18. 7.25%

19. 0.9%

20. 0.6%

C Change each decimal to a percent. [Examples 15–20] 21. 0.23

22. 0.34

23. 0.92

24. 0.87

25. 0.45

26. 0.54

27. 0.03

28. 0.04

29. 0.6

30. 0.9

31. 0.8

32. 0.5

33. 0.27

34. 0.62

35. 1.23

36. 2.34

339

340

Chapter 5 Percent

D Change each percent to a fraction in lowest terms. [Examples 21–23] 37. 60%

38. 40%

39. 75%

40. 25%

41. 4%

42. 2%

43. 26.5%

44. 34.2%

45. 71.87%

46. 63.6%

47. 0.75%

48. 0.45%

1 4

49. 6%

1 4

50. 5%

1 3

51. 33%

2 3

52. 66%

E Change each fraction or mixed number to a percent. [Examples 24–27] 53. 

1 2

54. 

1 4

55. 

3 4

56. 

4 5

60. 

1 6

61. 

7 8

62. 

59. 

1 4

65. 3 

21 43

1 8

66. 2 

69.  to the nearest tenth of a percent

1 2

67. 1 

2 3

57. 

1 3

58. 

1 8

63. 

7 50

64. 

3 4

68. 1 

36 49

70.  to the nearest tenth of a percent

1 5

9 25

5.1 Problem Set

341

Applying the Concepts 71. Mothers The chart shows the percentage of women who continue working after having a baby.

Working Women with Infants 1997

53.4%

1999

53.6%

2001 2002 2003

their energy.

Role of Renewable Energy In the U.S.

50.6%

1998

2000

72. U.S. Energy The pie chart shows where Americans get

Natural Gas 23% Coal 23%

52.7%

Renewable Energy 7% Nuclear Energy 8%

51.0%

Petroleum 40%

56.1% 53.7%

Source: U.S. Department of Labor

Source: Energy Information Adminstration 2006

Using the chart, convert the percentage for the follow-

Using the chart, convert the percentage to a fraction for

ing years to a decimal.

the following types of energy. Reduce to lowest terms.

a. 1997

a. Natural Gas

b. 2000

b. Nuclear Energy

c. 2003

c. Petroleum

73. Paying Bills According to Pew Research, a non-political

74. Pizza Ingredients The pie chart below shows the decimal

organization that provides information on the issues,

representation of each ingredient by weight that is used

attitudes and trends shaping America, most people still

to make a sausage and mushroom pizza. We see that

pay their monthly bills by check.

half of the pizza’s weight comes from the crust. Change each decimal to a percent.

Paying Bills

Mushroom and Sausage Pizza Crust 0.5 Check 54% Electronic/Online 28%

Cheese 0.25

Cash 15%

Sausage 0.075

Other 3%

Mushrooms 0.05 Tomato Sauce 0.125

a. Convert each percent to a fraction. b. Convert each percent to a decimal. c. About how many times more likely are you to pay a bill with a check than by electronic or online methods?

342

Chapter 5 Percent

Calculator Problems Use a calculator to write each fraction as a decimal, and then change the decimal to a percent. Round all answers to the nearest tenth of a percent. 29 37

18 83

75. 

6 51

76. 

77. 

8 95

568 732

236 327

78. 

79. 

80. 

Getting Ready for the Next Section Multiply.

81. 0.25(74)

82. 0.15(63)

83. 0.435(25)

84. 0.635(45)

Divide. Round the answers to the nearest thousandth, if necessary. 21 42

25 0.4

21 84

85. 

86. 

31.9 78

87. 

88. 

Solve for n.

90. 25  0.40n

89. 42n  21

Maintaining Your Skills Write as a decimal. 1 8

92. 

1 16

96. 

91. 

95. 

3 8

93. 

5 8

94. 

3 16

97. 

7 8

5 16

98. 

7 16

Divide. 1 8

1 16

99.   

103. 0.125  0.0625

3 8

3 16

5 8

5 16

7 8

7 16

100.   

101.   

102.   

104. 0.375  0.1875

105. 0.625  0.3125

106. 0.875  0.4375

Basic Percent Problems

5.2 Objectives A Solve the three types of percent

Introduction . . . The American Dietetic Association (ADA) recommends eating foods in which the number of calories from fat is less than 30% of the total number of calories. Foods that satisfy this requirement are considered healthy foods. Is the nutrition label shown below from a food that the ADA would consider healthy? This is the type of question we will be able to answer after we have worked through the ex-

problems.

B

Solve percent problems involving food labels.

C

Solve percent problems using proportions.

amples in this section.

Nutrition Facts Examples now playing at

Serving Size 1/2 cup (65g) Servings Per Container: 8

MathTV.com/books

Amount Per Serving Calories 150

Calories from fat 90

Total Fat 10g

% Daily Value* 16%

Saturated Fat 6g Cholesterol 35mg

32% 12%

Sodium 30mg

1%

Total Carbohydrate 14g Dietary Fiber 0g

5% 0%

Sugars 11g Protein 2g Vitamin A 6% Calcium 6%

• •

Vitamin C 0% Iron 0%

*Percent Daily Values are based on a 2,000 calorie diet.

FIGURE 1 Nutrition label from vanilla ice cream This section is concerned with three kinds of word problems that are associated with percents. Here is an example of each type: Type A:

What number is 15% of 63?

Type B:

What percent of 42 is 21?

Type C:

25 is 40% of what number?

A Solving Percent Problems Using Equations The first method we use to solve all three types of problems involves translating the sentences into equations and then solving the equations. The following translations are used to write the sentences as equations: English is of a number what number what percent

Mathematics   (multiply) n n n

The word is always translates to an  sign. The word of almost always means multiply. The number we are looking for can be represented with a letter, such as n or x.

5.2 Basic Percent Problems

343

344 PRACTICE PROBLEMS 1. a. What number is 25% of 74? b. What number is 50% of 74?

Chapter 5 Percent

EXAMPLE 1 SOLUTION

What number is 15% of 63?

We translate the sentence into an equation as follows: What number is 15% of 63?

g g g g g

n  0.15  63

To do arithmetic with percents, we have to change to decimals. That is why 15% is rewritten as 0.15. Solving the equation, we have n  0.15  63 n  9.45 15% of 63 is 9.45

2. a. What percent of 84 is 21? b. What percent of 84 is 42?

EXAMPLE 2 SOLUTION

What percent of 42 is 21?

We translate the sentence as follows: What percent of 42 is 21?

ggg g g

n  42  21

We solve for n by dividing both sides by 42. 21 n  42     42 4 2  21 n  42 n  0.50 Because the original problem asked for a percent, we change 0.50 to a percent: n  50% 21 is 50% of 42

3. a. 35 is 40% of what number? b. 70 is 40% of what number?

EXAMPLE 3 SOLUTION

25 is 40% of what number?

Following the procedure from the first two examples, we have 25 is 40% of what number?

g g g gg

25  0.40  n Again, we changed 40% to 0.40 so we can do the arithmetic involved in the problem. Dividing both sides of the equation by 0.40, we have 25 0.  40  n    0.40 0 .40  25  n 0.40 62.5  n 25 is 40% of 62.5 Answers 1. a. 18.5 b. 37 2. a. 25% b. 50% 3. a. 87.5 b. 175

As you can see, all three types of percent problems are solved in a similar manner. We write is as , of as , and what number as n. The resulting equation is then solved to obtain the answer to the original question.

345

5.2 Basic Percent Problems

EXAMPLE 4

4. What number is 63.5% of 45?

What number is 43.5% of 25?

g g

gg g

(Round to the nearest tenth.)

n  0.435  25

n  10.9

Rounded to the nearest tenth

10.9 is 43.5% of 25

EXAMPLE 5

5. What percent of 85 is 11.9?

What percent of 78 is 31.9?

ggg g g

n  78  31.9

n  78  31.9    7 8 78  31.9 n  78 n  0.409

Rounded to the nearest thousandth

n  40.9% 40.9% of 78 is 31.9

EXAMPLE 6

6. 62 is 39% of what number?

34 is 29% of what number?

g g g gg

(Round to the nearest tenth.)

34  0.29  n

0.  29  n 34     0 .29 0.29  34  n 0.29 117.2  n

Rounded to the nearest tenth

34 is 29% of 117.2

B Food Labels EXAMPLE 7

7. The nutrition label below is

As we mentioned in the introduction to this section, the

American Dietetic Association recommends eating foods in which the number of calories from fat is less than 30% of the total number of calories. According to the nutrition label below, what percent of the total number of calories is fat calories?

from a package of vanilla frozen yogurt. What percent of the total number of calories is fat calories? Round your answer to the nearest tenth of a percent.

Nutrition Facts

Nutrition Facts

Serving Size 1/2 cup (98g) Servings Per Container: 4

Serving Size 1/2 cup (65g) Servings Per Container: 8

Amount Per Serving Calories from fat 25

Calories 160

Amount Per Serving

% Daily Value* 4%

Total Fat 2.5g

Calories 150

Calories from fat 90

Total Fat 10g

% Daily Value* 16%

Saturated Fat 6g Cholesterol 35mg

32% 12%

Sodium 30mg

1%

Total Carbohydrate 14g Dietary Fiber 0g

5% 0%

Sugars 11g

Saturated Fat 1.5g Cholesterol 45mg

7% 15%

Sodium 55mg

2%

Total Carbohydrate 26g Dietary Fiber 0g

9% 0%

Sugars 19g Protein 8g Vitamin A 0% Calcium 25%

• •

Vitamin C 0% Iron 0%

*Percent Daily Values are based on a 2,000 calorie diet.

Protein 2g Vitamin A 6% Calcium 6%

• •

Vitamin C 0% Iron 0%

*Percent Daily Values are based on a 2,000 calorie diet.

FIGURE 2 Nutrition label from vanilla ice cream

Answers 4. 28.6 5. 14% 6. 159.0

346

Chapter 5 Percent

SOLUTION

To solve this problem, we must write the question in the form of

one of the three basic percent problems shown in Examples 1–6. Because there are 90 calories from fat and a total of 150 calories, we can write the question this way: 90 is what percent of 150? Now that we have written the question in the form of one of the basic percent problems, we simply translate it into an equation. Then we solve the equation. 90 is what percent of 150?

g g g

88 8 888888888 8m 8 m

90  n  150 90  n 150

n  0.60  60% The number of calories from fat in this package of ice cream is 60% of the total number of calories. Thus the ADA would not consider this to be a healthy food.

C Solving Percent Problems Using Proportions We can look at percent problems in terms of proportions also. For example, we 6 24 know that 24% is the same as  , which reduces to  . That is 100 25 24  100

h

6  25



h

h

{ { 24 is to 100

as

6 is to 25

We can illustrate this visually with boxes of proportional lengths:

24

6

100

25

In general, we say Percent  100

h



h

Amount  Base

h

{ { Percent is to 100

Answer 7. 15.6% of the calories are from fat. (So far as fat content is concerned, the frozen yogurt is a healthier choice than the ice cream.)

as

Amount is to Base

347

5.1 Percents, Decimals, and Fractions

EXAMPLE 8 SOLUTION

What number is 15% of 63?

This is the same problem we worked in Example 1. We let n be the

8. Rework Practice Problem 1 using proportions.

number in question. We reason that n will be smaller than 63 because it is only 15% of 63. The base is 63 and the amount is n. We compare n to 63 as we compare 15 to 100. Our proportion sets up as follows: as

n is to 63

{ {

15 is to 100

h

h

h

15  100



n  63

15

n

100

63

Solving the proportion, we have 15  63  100n

Extremes/means property Simplify the left side Divide each side by 100

945  100n 9.45  n

This gives us the same result we obtained in Example 1.

EXAMPLE 9 SOLUTION

What percent of 42 is 21?

This is the same problem we worked in Example 2. We let n be the

9. Rework Practice Problem 2 using proportions.

percent in question. The amount is 21 and the base is 42. We compare n to 100 as we compare 21 to 42. Here is our reasoning and proportion: as

21 is to 42

{ {

n is to 100

h

h

h

n  100



21  42

n

21

100

42

Solving the proportion, we have 42n  21  100 42n  2,100 n  50

Extremes/means property Simplify the right side Divide each side by 42

Since n is a percent, our answer is 50%, giving us the same result we obtained in Example 2.

Answers 8. a. 18.5 b. 37 9. a. 25% b. 50%

348 10. Rework Practice Problem 3

Chapter 5 Percent

EXAMPLE 10

using proportions.

SOLUTION

25 is 40% of what number?

This is the same problem we worked in Example 3. We let n be the

number in question. The base is n and the amount is 25. We compare 25 to n as we compare 40 to 100. Our proportion sets up as follows: as

25 is to n

h

h

h



25  n

{ {

40 is to 100

40  100

Note

When you work the problems in the problem set, use whichever method you like, unless your instructor indicates that you are to use one method instead of the other.

40

25

100

n

Solving the proportion, we have 40  n  25  100 40  n  2,500 n  62.5

Extremes/means property Simplify the right side Divide each side by 40

So, 25 is 40% of 62.5, which is the same result we obtained in Example 3.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. When we translate a sentence such as “What number is 15% of 63?” into symbols, what does each of the following translate to?

a. is

b. of

c. what number

2. Look at Example 1 in your text and answer the question below. The number 9.45 is what percent of 63? 3. Show that the answer to the question below is the same as the answer to the question in Example 2 of your text. The number 21 is what percent of 42? 4. If 21 is 50% of 42, then 21 is what percent of 84?

Answer 10. a. 87.5 b. 175

5.2 Problem Set

Problem Set 5.2 A

C Solve each of the following problems. [Examples 1–6]

1. What number is 25% of 32?

2. What number is 10% of 80?

3. What number is 20% of 120?

4. What number is 15% of 75?

5. What number is 54% of 38?

6. What number is 72% of 200?

7. What number is 11% of 67?

8. What number is 2% of 49?

9. What percent of 24 is 12?

10. What percent of 80 is 20?

11. What percent of 50 is 5?

12. What percent of 20 is 4?

13. What percent of 36 is 9?

14. What percent of 70 is 14?

15. What percent of 8 is 6?

16. What percent of 16 is 9?

17. 32 is 50% of what number?

18. 16 is 20% of what number?

19. 10 is 20% of what number?

20. 11 is 25% of what number?

21. 37 is 4% of what number?

22. 90 is 80% of what number?

23. 8 is 2% of what number?

24. 6 is 3% of what number?

349

350 A

Chapter 5 Percent

C The following problems can be solved by the same method you used in Problems 1–24. [Examples 1–6]

25. What is 6.4% of 87?

26. What is 10% of 102?

27. 25% of what number is 30?

28. 10% of what number is 22?

29. 28% of 49 is what number?

30. 97% of 28 is what number?

31. 27 is 120% of what number?

32. 24 is 150% of what number?

33. 65 is what percent of 130?

34. 26 is what percent of 78?

35. What is 0.4% of 235,671?

36. What is 0.8% of 721,423?

37. 4.89% of 2,000 is what number?

38. 3.75% of 4,000 is what number?

39. Write a basic percent problem, the solution to which

40. Write a basic percent problem, the solution to which

can be found by solving the equation n  0.25(350).

can be found by solving the equation n  0.35(250).

41. Write a basic percent problem, the solution to which

42. Write a basic percent problem, the solution to which

can be found by solving the equation n  24  16.

can be found by solving the equation n  16  24.

43. Write a basic percent problem, the solution to which

44. Write a basic percent problem, the solution to which

can be found by solving the equation 46  0.75  n.

can be found by solving the equation 75  0.46  n.

5.2 Problem Set

B

Applying the Concepts

351

[Example 7]

Nutrition For each nutrition label in Problems 45–48, find what percent of the total number of calories comes from fat calories. Then indicate whether the label is from a food considered healthy by the American Dietetic Association. Round to the nearest tenth of a percent if necessary.

45. Spaghetti

46. Canned Italian tomatoes

Nutrition Facts

Nutrition Facts

Serving Size 2 oz. (56g per 1/8 of pkg) dry Servings Per Container: 8

Serving Size 1/2 cup (121g) Servings Per Container: about 3 1/2

Amount Per Serving

Amount Per Serving

Calories 210

Calories from fat 10

Calories 25

% Daily Value* 2%

Total Fat 0g

Total Fat 1g Saturated Fat 0g

0%

Polyunsaturated Fat 0.5g

Calories from fat 0 % Daily Value* 0% 0%

Saturated Fat 0g Cholesterol 0mg

0%

Monounsaturated Fat 0g Cholesterol 0mg

0%

Potassium 145mg

4%

Sodium 0mg

0%

Total Carbohydrate 4g Dietary Fiber 1g

2%

Sodium 300mg

Total Carbohydrate 42g Dietary Fiber 2g

14% 7%

Sugars 3g

Calcium 0% Thiamin 30% Niacin 15%

4%

Sugars 4g Protein 1g

Protein 7g Vitamin A 0%

12%

Vitamin A 20%

• • • •

Vitamin C 0% Iron 10% Riboflavin 10%

Calcium 4%

• •

Vitamin C 15% Iron 15%

*Percent Daily Values are based on a 2,000 calorie diet.

*Percent Daily Values are based on a 2,000 calorie diet

47. Shredded Romano cheese

48. Tortilla chips

Nutrition Facts

Nutrition Facts

Serving Size 2 tsp (5g) Servings Per Container: 34

Serving Size 1 oz (28g/About 12 chips) Servings Per Container: about 2

Amount Per Serving

Amount Per Serving Calories from fat 10

Calories 20

% Daily Value* 2%

Total Fat 1.5g

Calories from fat 60

Calories 140

% Daily Value* 1%

Total Fat 7g

Saturated Fat 1g Cholesterol 5mg

5%

Saturated Fat 1g Cholesterol 0mg

6%

2%

Sodium 70mg

3%

Sodium 170mg

7%

Total Carbohydrate 0g Fiber 0g

0%

Total Carbohydrate 18g Dietary Fiber 1g

6%

0%

Protein 2g

Protein 2g

Calcium 4%

4%

Sugars less than 1g

Sugars 0g

Vitamin A 0%

0%

• •

Vitamin C 0% Iron 0%

*Percent Daily Values are based on a 2,000 calorie diet.

Vitamin A 0% Calcium 4%

• •

Vitamin C 0% Iron 2%

*Percent Daily Values are based on a 2,000 calorie diet.

352

Chapter 5 Percent

Getting Ready for the Next Section Solve each equation.

49. 96  n  120

50. 2,400  0.48  n

51. 114  150n

52. 3,360  0.42n

53. What number is 80% of 60?

54. What number is 25% of 300?

Maintaining Your Skills Multiply.

55. 2  0.125

56. 3  0.125

59. The sequence below is an arithmetic sequence in which each term is found by adding

1  8

to the previous

term. Find the next three numbers in the sequence.

57. 4  0.125

58. 5  0.125

60. The sequence below is an arithmetic sequence in 1

to the previous which each term is found by adding 1 6 term. Find the next three numbers in the sequence. 1 3 1 , , , . . . 8 16 4

1 3 1 , , , . . . 4 8 2 Simplify. 1 4

1 8

1 2

3 8

7 8

61.       

3 4

5 8

1 2

62.       

Write as a decimal. 2 8

64. 

2 16

68. 

63. 

67. 

4 8

65. 

6 8

66. 

4 16

69. 

6 16

70. 

Write in order from smallest to largest. 3 1 5 1 1 3 7 8 4 8 8 2 4 8

71. , , , , , , 

3 1 1 3 7 1 1 5 16 8 4 8 16 16 2 16

72. , , , , , , , 

8 8

8 16

General Applications of Percent

5.3 Objectives A Solve application problems

Introduction . . . As you know from watching television and reading the newspaper, we encounter

involving percent.

percents in many situations in everyday life. A recent newspaper article discussing the effects of a cholesterol-lowering drug stated that the drug in question “lowered levels of LDL cholesterol by an average of 35%.” As we progress through this chapter, we will become more and more familiar with percent. As a

Examples now playing at

result, we will be better equipped to understand statements like the one above

MathTV.com/books

concerning cholesterol. In this section we continue our study of percent by doing more of the translations that were introduced in Section 5.2. The better you are at working the problems in Section 5.2, the easier it will be for you to get started on the problems in this section.

A Applications Involving Percent PRACTICE PROBLEMS

EXAMPLE 1

On a 120-question test, a student answered 96 correctly.

What percent of the problems did the student work correctly?

SOLUTION

We have 96 correct answers out of a possible 120. The problem can

1. On a 150-question test, a student answered 114 correctly. What percent of the problems did the student work correctly?

be restated as

m8 m8 m8

96 is what percent of 120? 888 888 8888 8888 m88 m88 96  n  120

96 n 120    120 1 20  96 n  120 n  0.80  80%

Divide both sides by 120 Switch the left and right sides of the equation Divide 96 by 120 Rewrite as a percent

When we write a test score as a percent, we are comparing the original score to an equivalent score on a 100-question test. That is, 96 correct out of 120 is the same as 80 correct out of 100.

EXAMPLE 2

How much HCl (hydrochloric acid) is in a 60-milliliter bot-

40-milliliter bottle that is marked 75% HCl?

tle that is marked 80% HCl?

SOLUTION

2. How much HCl is in a

If the bottle is marked 80% HCl, that means 80% of the solution is

HCl and the rest is water. Because the bottle contains 60 milliliters, we can restate the question as: What is 80% of 60? g g g g g n  0.80  60 n  48 HCL 80% 60 m l

There are 48 milliliters of HCl in 60 milliliters of 80% HCl solution.

5.3 General Applications of Percent

Answers 1. 76% 2. 30 milliliters

353

354

3. If 42% of the students in a certain college are female and there are 3,360 female students, what is the total number of students in the college?

Chapter 5 Percent

EXAMPLE 3

If 48% of the students in a certain college are female and

there are 2,400 female students, what is the total number of students in the college?

SOLUTION

We restate the problem as: 2,400 is 48% of what number? g g g g g 2,400  0.48  n 2,400 0.  48  n    0.48 0 .48  2,400 n  0.48

Divide both sides by 0.48 Switch the left and right sides of the equation

n  5,000 There are 5,000 students.

4. Suppose in Example 4 that 35% of the students receive a grade of A. How many of the 300 students is that?

EXAMPLE 4

If 25% of the students in elementary algebra courses re-

ceive a grade of A, and there are 300 students enrolled in elementary algebra this year, how many students will receive As?

SOLUTION

After reading the question a few times, we find that it is the same as

this question: What number is 25% of 300? g g g g g n  0.25  300 n  75 Thus, 75 students will receive A’s in elementary algebra.

Almost all application problems involving percents can be restated as one of the three basic percent problems we listed in Section 5.2. It takes some practice before the restating of application problems becomes automatic. You may have to review Section 5.2 and Examples 1–4 above several times before you can translate word problems into mathematical expressions yourself.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. On the test mentioned in Example 1, how many questions would the student have answered correctly if she answered 40% of the questions correctly? 2. If the bottle in Example 2 contained 30 milliliters instead of 60, what would the answer be? 3. In Example 3, how many of the students were male? 4. How many of the students mentioned in Example 4 received a grade lower than A?

Answers 3. 8,000 students 4. 105 students

5.3 Problem Set

355

Problem Set 5.3 A Solve each of the following problems by first restating it as one of the three basic percent problems of Section 5.2. In each case, be sure to show the equation. [Examples 1–4]

1. Test Scores On a 120-question test a student answered

2. Test Scores An engineering student answered 81 ques-

84 correctly. What percent of the problems did the stu-

tions correctly on a 90-question trigonometry test.

dent work correctly?

What percent of the questions did she answer correctly? What percent were answered incorrectly?

3. Basketball A basketball player made 63 out of 75 free throws. What percent is this?

4. Family Budget A family spends $450 every month on food. If the family’s income each month is $1,800, what percent of the family’s income is spent on food?

5. Chemistry How much HCl (hydrochloric acid) is in a 60milliliter bottle that is marked 75% HCl?

6. Chemistry How much acetic acid is in a 5-liter container of acetic acid and water that is marked 80% acetic acid? How much is water?

7. Farming A farmer owns 28 acres of land. Of the 28

8. Number of Students Of the 420 students enrolled in a

acres, only 65% can be farmed. How many acres are

basic math class, only 30% are first-year students. How

available for farming? How many are not available for

many are first-year students? How many are not?

farming?

9. Determining a Tip Servers and wait staff are often paid

10. Determining a Tip Suppose you decide to leave a 15% tip

minimum wage and depend on tips for much of their

for services after your dinner out in the preceding prob-

income. It is common for tips to be 15% to 20% of the

lem. How much of a tip did you leave your server?

bill. After dinner at a local restaurant the total bill is

How much smaller was the tip?

$56.00. Since your service was above average you decide to give a 20% tip. Determine the amount of the tip you leave for your server.

11. Voting In the 2004 Presidential election, George Bush

12. Census Data According to the U.S. Census Bureau,

received 53.25% of the total electoral votes and John

national population estimates grouped by age and

Kerry received 46.75% of the total electoral votes. If

gender for July, 2006, approximately 7.4% of the

there were 537 total votes cast by the Electoral College

147,512,152 males in our population are between the

how many electoral votes did each candidate receive?

ages of 15 and 19 years old. How many males are in this age group?

356

Chapter 5 Percent

13. Bachelors According to the U.S. Census Bureau data for

14. Bachelorettes According to the U.S. Census Bureau data

the number of marriages in 2004 approximately 31.2%

for the number of marriages in 2004, approximately

of the 109,830,000 males age 15 years or older have

25.8 % of the 117,677,000 females age 15 years or older

never been married. How many males age 15 years or

have never been married. How many females age 15

older have never been married?

years or older have never been married?

15. Number of Students If 48% of the students in a certain

16. Mixture Problem A solution of alcohol and water is 80%

college are female and there are 1,440 female stu-

alcohol. The solution is found to contain 32 milliliters

dents, what is the total number of students in the

of alcohol. How many milliliters total (both alcohol

college?

and water) are in the solution?

Tom Stewart/Corbis

Alcohol 80%

17. Number of Graduates Suppose 60% of the graduating

18. Defective Parts In a shipment of airplane parts, 3% are

class in a certain high school goes on to college. If 240

known to be defective. If 15 parts are found to be

students from this graduating class are going on to

defective, how many parts are in the shipment?

college, how many students are there in the graduating class?

19. Number of Students There are 3,200 students at our

20. Number of Students In a certain school, 75% of the stu-

school. If 52% of them are female, how many female

dents in first-year chemistry have had algebra. If there

students are there at our school?

are 300 students in first-year chemistry, how many of them have had algebra?

21. Population In a city of 32,000 people, there are 10,000

22. Number of Students If 45 people enrolled in a psychol-

people under 25 years of age. What percent of the pop-

ogy course but only 35 completed it, what percent of

ulation is under 25 years of age?

the students completed the course? (Round to the nearest tenth of a percent.)

5.3 Problem Set

357

Calculator Problems The following problems are similar to Problems 1–22. They should be set up the same way. Then the actual calculations should be done on a calculator.

23. Number of People Of 7,892 people attending an outdoor

24. Manufacturing A car manufacturer estimates that 25% of

concert in Los Angeles, 3,972 are over 18 years of age.

the new cars sold in one city have defective engine

What percent is this? (Round to the nearest whole-

mounts. If 2,136 new cars are sold in that city, how

number percent.)

many will have defective engine mounts?

25. Population The map shows the most populated cities in

26. Prom The graph shows how much girls plan to spend

the United States. If the population of New York City is

on the prom. If 5,086 girls were surveyed, how many

about 42% of the state’s population, what is the approx-

are planning on spending less than $200 on the prom?

imate population of the state?

Round to the nearest whole number.

Where Is Everyone? Los Angeles, CA San Diego, CA Phoeniz, AZ Dallas, TX Houston, TX Chicago, IL Philadelphia, PA

The Cost of Looking Good

3.80 1.26 1.37 1.21 2.01 2.89 1.49

29%

Less than $200

34%

$200 - $400 19%

$400 - $600 11%

More than $600 Takin’ out a loan

7%

8.08

New York City, NY

Source: www.thepromsite.com 5,086 total votes

Source: U.S. Census Bureau

Getting Ready for the Next Section Multiply.

27. 0.06(550)

28. 0.06(625)

29. 0.03(289,500)

30. 0.03(115,900)

33. 19.80  396

34. 11.82  197

Divide. Write your answers as decimals.

31. 5.44  0.04 1,836 0.12

35. 

32. 4.35  0.03 115 0.1

36. 

90 600

37. 

105 750

38. 

358

Chapter 5 Percent

Maintaining Your Skills The problems below review multiplication with fractions and mixed numbers. Multiply. 1 2

3 4

2 5

39.   

1 3

40.   

3 8

5 12

43. 2  

44. 3  

3 4

5 9

41.   

1 4

8 15

45. 1   

5 6

12 13

42.   

1 3

9 10

46. 2   

Extending the Concepts: Batting Averages Batting averages in baseball are given as decimal numbers, rounded to the nearest thousandth. For example, at the end of June 2008, Milton Bradley had the highest batting average in the American League. At that time, he had 76 hits in 235 times at bat. His batting average was .323, which is found by dividing the number of hits by the number of times he was at bat and then rounding to the nearest thousandth. number of hits 76 Batting average      0.323 number of times at bat 235 Because we can write any decimal number as a percent, we can convert batting averages to percents and use our knowledge of percent to solve problems. Looking at Milton Bradley’s batting average as a percent, we can say that he will get a hit 32.3% of the times he is at bat. Each of the following problems can be solved by converting batting averages to percents and translating the problem into one of our three basic percent problems. (All numbers are from the end of June 2008.)

47. Chipper Jones had the highest batting average in the National League with 100 hits in 254 times at bat. What

48. Sammy Sosa had 104 hits in 412 times at bat. What percent of the time can we expect Sosa to get a hit?

percent of the time Chipper Jones is at bat can we expect him to get a hit?

49. Barry Bonds was batting

50. Joe Mauer was batting .321. If he had been at bat 265 times, how many hits did he have? (Remember,

bat 340 times, how many

his batting average has been rounded to the nearest

hits did he have?

thousandth.)

(Remember his batting average has been rounded to the nearest thousandth.)

Peter DeSilva/Corbis Sygma

.276. If he had been at

51. How many hits must Milton Bradley have in his next 50

52. How many hits must Chipper Jones have in his next 50

times at bat to maintain a batting average of at least

times at bat to maintain a batting average of at least

.323?

.394?

Sales Tax and Commission To solve the problems in this section, we will first restate them in terms of the problems we have already learned how to solve.

5.4 Objectives A Solve application problems involving sales tax.

B

A Sales Tax EXAMPLE 1

Solve application problems involving commission.

Suppose the sales tax rate in Mississippi is 6% of the pur-

chase price. If the price of a refrigerator is $550, how much sales tax must be

Examples now playing at

paid?

SOLUTION

MathTV.com/books Because the sales tax is 6% of the purchase price, and the purchase

price is $550, the problem can be restated as:

PRACTICE PROBLEMS What is 6% of $550?

1. What is the sales tax on a new

We solve this problem, as we did in Section 5.2, by translating it into an equation: What is 6% of $550? g g g g g n  0.06  550

Note

n  33 The sales tax is $33. The total price of the refrigerator would be Sales tax 

$33

m8

m8 $550

EXAMPLE 2

Total price

m8

Purchase price



$583

In Example 1, the sales tax rate is 6%, and the sales tax is $33. In most everyday communications, people say “The sales tax is 6%,” which is incorrect. The 6% is the tax rate, and the $33 is the actual tax.

Suppose the sales tax rate is 4%. If the sales tax on a 10-

speed bicycle is $5.44, what is the purchase price, and what is the total price of the bicycle?

SOLUTION

washing machine if the machine is purchased for $625 and the sales tax rate is 6%?

We know that 4% of the purchase price is $5.44. We find the pur-

chase price first by restating the problem as:

2. Suppose the sales tax rate is 3%. If the sales tax on a 10speed bicycle is $4.35, what is the purchase price, and what is the total price of the bicycle?

$5.44 is 4% of what number? g g g g g 5.44  0.04  n We solve the equation by dividing both sides by 0.04: 5.44 0.  04  n    0.04 0 .04 

Divide both sides by 0.04

5.44 n  0.04

Switch the left and right sides of the equation

n  136

Divide

The purchase price is $136. The total price is the sum of the purchase price and the sales tax. Purchase price  $136.00 Sales tax



Total price

 $141.44



5.44

Answers 1. $37.50 2. $145; $149.35

5.4 Sales Tax and Commission

359

360

Chapter 5 Percent

3. Suppose the purchase price of two speakers is $197 and the sales tax is $11.82. What is the sales tax rate?

EXAMPLE 3

Suppose the purchase price of a stereo system is $396 and

the sales tax is $19.80. What is the sales tax rate?

SOLUTION

We restate the problem as: $19.80 is what percent 8 of $396? g g g 88888 8888 m888 m8888 19.80  n  396

To solve this equation, we divide both sides by 396: 19.80 n 396    396 3 96  19.80 n  396 n  0.05 n  5%

Divide both sides by 396 Switch the left and right sides of the equation Divide 0.05  5%

The sales tax rate is 5%.

B Commission Many salespeople work on a commission basis. That is, their earnings are a percentage of the amount they sell. The commission rate is a percent, and the actual commission they receive is a dollar amount.

4. A real estate agent gets 3% of the price of each house she sells. If she sells a house for $115,000, how much money does she earn?

EXAMPLE 4

A real estate agent gets 3% of the price of each house she

sells. If she sells a house for $289,500, how much money does she earn?

SOLUTION

The commission is 3% of the price of the house, which is $289,500.

We restate the problem as: What is 3% of $289,500? g g g g g n  0.03  289,500 n  8,685 The commission is $8,685.

5. An appliance salesperson’s commission rate is 10%. If the commission on one of the ovens is $115, what is the purchase price of the oven?

EXAMPLE 5

Suppose a car salesperson’s commission rate is 12%. If the

commission on one of the cars is $1,836, what is the purchase price of the car?

SOLUTION

12% of the sales price is $1,836. The problem can be restated as: 12% 888of what 8 number 8is $1,836? 8 8 8 n 888n8n m8 m8 0.12  n  1,836 0.  12  n 1,836    0 .12 0.12  n  15,300

The car sells for $15,300.

Answers 3. 6% 4. $3,450

5. $1,150

Divide both sides by 0.12

361

5.4 Sales Tax and Commission

EXAMPLE 6

If the commission on a $600 dining room set is $90, what

sofa is $105, what is the commission rate?

is the commission rate?

SOLUTION

6. If the commission on a $750

The commission rate is a percentage of the selling price. What we

want to know is:

8

88

n

m

8 888

$908 is what percent of $600? 88 888 8 88 88 88 8n 8n m 90  n  600 90 n 600    600 6 00  90 n  600 n  0.15 n  15%

Divide both sides by 600 Switch the left and right sides of the equation Divide Change to a percent

The commission rate is 15%.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Explain the difference between the sales tax and the sales tax rate. 2. Rework Example 1 using a sales tax rate of 7% instead of 6%. 3. Suppose the bicycle in Example 2 was purchased in California, where the sales tax rate in 2008 was 7.25%. How much more would the bicycle have cost? 4. Suppose the car salesperson in Example 5 receives a commission of $3,672. Assuming the same commission rate of 12%, how much does this car sell for?

Answer 6. 14%

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5.4 Problem Set

363

Problem Set 5.4 A These problems should be solved by the method shown in this section. In each case show the equation needed to solve the problem. Write neatly, and show your work. [Examples 1–3]

1. Sales Tax Suppose the sales tax rate in Mississippi is 7%

2. Sales Tax If the sales tax rate is 5% of the purchase

of the purchase price. If a new food processor sells for

price, how much sales tax is paid on a television that

$750, how much is the sales tax?

sells for $980?

3. Sales Tax and Purchase Price Suppose the sales tax rate in

4. Sales Tax and Purchase Price Suppose the sales tax rate in

Michigan is 6%. How much is the sales tax on a $45

Hawaii is 4%. How much tax is charged on a new car if

concert ticket? What is the total price?

the purchase price is $16,400? What is the total price?

5. Total Price The sales tax rate is 4%. If the sales tax on a

6. Total Price The sales tax on a new microwave oven is

10-speed bicycle is $6, what is the purchase price?

$30. If the sales tax rate is 5%, what is the purchase

What is the total price?

price? What is the total price?

7. Tax Rate Suppose the pur-

8. Tax Rate If the purchase price

chase price of a dining room

of a bottle of California wine is

set is $450. If the sales tax is

$24 and the sales tax is $1.50,

$22.50, what is the sales tax

what is the sales tax rate?

rate?

9. Energy The chart shows the cost to install either solar

10. Prom The graph shows how much guys plan to spend

panels or a wind turbine. A farmer is installing the

on prom. The sum of the tax on all the expenses a guy

equipment to generate energy from the wind. If he lives

had for prom was $15.75. If he lived in a state that has

in a state that has a 6% sales tax rate, how much did

a sales tax rate of 7.5%, what spending bracket would

the farmer pay in sales tax on the total equipment cost?

he have been in?

Solar Versus Wind Energy Costs Equipment Co

st:

$620 0 Modules $1570 Fi xed Rack ller $971 Charge Cont ro $4 40 Cable $9181 TOTA L

Handsome At What Cost?

Equipment Co Tu rbine Tower Cable TOTA L

st:

19%

0 - $100

$330 0 $300 0 $715 $7015

Source: a Limited 2006

27%

$100 - $200 $200 - $300

20%

$300 - $400

17%

Takin’ out a loan

17%

Source: www.thepromsite.com 636 total votes

364

Chapter 5 Percent

B [Examples 4–6] 11. Commission A real estate agent has a commission rate

12. Commission A tire salesperson has a 12% commission

of 3%. If a piece of property sells for $94,000, what is

rate. If he sells a set of radial tires for $400, what is his

her commission?

commission?

13. Commission and Purchase Price Suppose a salesperson

14. Commission and Purchase Price If an appliance salesper-

gets a commission rate of 12% on the lawnmowers she

son gets 9% commission on all the appliances she sells,

sells. If the commission on one of the mowers is $24,

what is the price of a refrigerator if her commission is

what is the purchase price of the lawnmower?

$67.50?

15. Commission Rate If the commission on an $800 washer is $112, what is the commission rate?

16. Commission Rate A realtor makes a commission of $11,400 on a $190,000 house he sells. What is his commission rate?

17. Phone Bill You recently received your monthly phone

18. Wireless Phone Bill You recently received your Verizon

bill for service in your local area. The total of the bill

wireless phone bill for the month. The total monthly

was $53.35. You pay $14.36 in surcharges and federal

bill is $70.52. Included in that total is $13.27 in sur-

and local taxes. What percent of your phone bill is

charges and taxes. What percent of your wireless bill

made up of surcharges and taxes? Round your answer

goes towards surcharges and taxes? Round your an-

to the nearest tenth of a percent.

swer to the nearest tenth of a percent.

19. Gasoline Tax New York state has one of the highest

20. Cigarette Tax In an effort to encourage people to quit

gasoline taxes in the country. If gas is currently selling

smoking, many states place a high tax on a pack of

at $4.27 for a gallon of regular gas and the tax rate is

cigarettes. Nine states place a tax of $2.00 or more on a

14.7%, how much of the price of a gallon of gas goes

pack of cigarettes, with New Jersey being the highest at

towards taxes?

$2.575 per pack. If this is 39% of the cost of a pack of cigarettes in New Jersey, how much does a single pack cost?

21. Salary Plus Commission A computer salesperson earns a

22. Salary Plus Bonus The manager for a computer store is

salary of $425 a week and a 6% commission on all

paid a weekly salary of $650 plus a bonus amounting

sales over $4000 each week. Suppose she was able to

to 1.5% of the net earnings of the store each week. Find

sell $6,250 in computer parts and accessories one

her total salary for the week when earnings for the

week. What was her salary for the week?

store are $26,875.56. Round your answer to the nearest cent.

5.4 Problem Set

365

Calculator Problems The following problems are similar to Problems 1–22. Set them up in the same way, but use a calculator for the calculations.

23. Sales Tax The sales tax rate on a certain item is 5.5%. If

24. Purchase Price If the sales tax rate is 4.75% and the sales

the purchase price is $216.95, how much is the sales

tax is $18.95, what is the purchase price? What is the

tax? (Round to the nearest cent.)

total price? (Both answers should be rounded to the nearest cent.)

25. Tax Rate The purchase price for a new suit is $229.50. If

26. Commission If the commission rate for a mobile home

the sales tax is $10.33, what is the sales tax rate?

salesperson is 11%, what is the commission on the sale

(Round to the nearest tenth of a percent.)

of a $15,794 mobile home?

27. Selling Price Suppose the commission rate on the sale

28. Commission Rate If the commission on the sale of $79.40

of used cars is 13%. If the commission on one of the

worth of clothes is $14.29, what is the commission

cars is $519.35, what did the car sell for?

rate? (Round to the nearest percent.)

Getting Ready for the Next Section Multiply.

29. 0.05(22,000)

30. 0.176(1,793,000)

31. 0.25(300)

32. 0.12(450)

Divide. Write your answers as decimals.

33. 4  25

34. 7  35

Subtract.

35. 25  21

36. 1,793,000  315,568

37. 450  54

Add.

39. 396  19.8

40. 22,000  1,100

38. 300  75

366

Chapter 5 Percent

Maintaining Your Skills The problems below review some basic concepts of division with fractions and mixed numbers. Divide. 2 3

1 3

43. 2  

5 9

2 3

47. 2   

41.   

1 3

2 3

42.   

3 8

1 4

46.   

45.   

3 4

1 4

1 2

44. 3  

1 2

1 4

1 2

48. 1   2 

Percent Increase or Decrease and Discount The table and bar chart below show some statistics compiled by insurance companies regarding stopping distances for automobiles traveling at 20 miles per hour on ice. Stopping Distance

Percent Decrease

Regular tires

150 ft

0

Snow tires

151 ft

1%

Studded snow tires

120 ft

20%

Reinforced tire chains

75 ft

50%

5.5 Objectives A Find the percent increase. B Find the percent decrease. C Solve application problems

involving the rate of discount.

Examples now playing at

MathTV.com/books

Source: Copyrighted table courtesy of The Casualty Adjuster’s Guide

Stopping distance (feet)

160

150

151

140 120 120 100 75

80 60 40 20 0 Regular tires

Snow tires

Studded snow tires

Reinforced tire chains

Many times it is more effective to state increases or decreases as percents, rather than the actual number, because with percent we are comparing everything to 100.

A Percent Increase EXAMPLE 1

PRACTICE PROBLEMS If a person earns $22,000 a year and gets a 5% increase in

SOLUTION

1. A person earning $18,000 a year gets a 7% increase in salary. What is the new salary?

salary, what is the new salary? We can find the dollar amount of the salary increase by finding 5% of

$22,000: 0.05  22,000  1,100 The increase in salary is $1,100. The new salary is the old salary plus the raise: $22,000 Old salary 

1,100 Raise (5% of $22,000) $23,100 New salary Answer 1. $19,260

5.5 Percent Increase or Decrease and Discount

367

368

Chapter 5 Percent

B Percent Decrease 2. In 1986, there were approximately 271,000 drunk drivers under correctional supervision (prison, jail, or probation). By 1997, that number had increased 89%. How many drunk drivers were under correctional supervision in 1997? Round to the nearest thousand.

EXAMPLE 2

In 1986, there were approximately 1,793,000 arrests for

driving under the influence of alcohol or drugs (DUI) in the United States. By 1997, the number of arrests for DUI had decreased 17.6% from the 1986 number. How many people were arrested for DUI in 1997? Round the answer to the nearest thousand.

SOLUTION

The decrease in the number of arrests is 17.6% of 1,793,000, or 0.176  1,793,000  315,568

Subtracting this number from 1,793,000, we have the number of DUI arrests in 1997.

Number of arrests in 1986 Decrease of 17.6% Number of arrests in 1997

1,793,000 

315,568 1,477,432

To the nearest thousand, there were approximately 1,477,000 arrests for DUI in 1997.

3. Shoes that usually sell for $35 are on sale for $28. What is the percent decrease in price?

EXAMPLE 3

Shoes that usually sell for $25 are on sale for $21. What is

the percent decrease in price?

SOLUTION

We must first find the decrease in price. Subtracting the sale price

from the original price, we have $25  $21  $4 The decrease is $4. To find the percent decrease (from the original price), we have n

$4 8is 8what percent of $25? 888 888 88 88 n n m m 4  n  25 4 n  25     25 2 5  4 n  25 n  0.16 n  16%

Divide both sides by 25 Switch the left and right sides of the equation Divide Change to a percent

The shoes that sold for $25 have been reduced by 16% to $21. In a problem like this, $25 is the original (or marked) price, $21 is the sale price, $4 is the discount, and 16% is the rate of discount.

C Discount Rate 4. During a sale, a microwave oven that usually sells for $550 is marked “15% off.” What is the discount? What is the sale price?

Answers 2. 512,000

EXAMPLE 4

During a clearance sale, a suit that usually sells for $300 is

marked “25% off.” What is the discount? What is the sale price?

SOLUTION

To find the discount, we restate the problem as: What is 25% of 300? g g g g g n  0.25  300

3. 20%

n  75

369

5.5 Percent Increase or Decrease and Discount The discount is $75. The sale price is the original price less the discount:

Original price Less the discount (25% of $300) Sale price

$300 

75 $225

EXAMPLE 5

A man buys a washing machine on sale. The machine

usually sells for $450, but it is on sale at 12% off. If the sales tax rate is 5%, how much is the total bill for the washer?

SOLUTION

First we have to find the sale price of the washing machine, and we

begin by finding the discount:

5. A woman buys a new coat on sale. The coat usually sells for $45, but it is on sale at 15% off. If the sales tax rate is 5%, how much is the total bill for the coat?

What is 12% of $450? g g g g g n  0.12  450 n  54

SALE

WASHING MACHINE

The washing machine is marked down $54. The sale price is $450 

54 $396

Original price Discount (12% of $450) Sale price

12% OFF Come in today for a 30 day test trial!

Because the sales tax rate is 5%, we find the sales tax as follows: What is 5% of 396? g g g g g n  0.05  396 n  19.80 The sales tax is $19.80. The total price the man pays for the washing machine is $396.00 

19.80 $415.80

Sale price Sales tax Total price

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Suppose the person mentioned in Example 1 was earning $32,000 per year and received the same percent increase in salary. How much more would the raise have been? 2. Suppose the shoes mentioned in Example 3 were on sale for $20, instead of $21. Calculate the new percent decrease in price. 3. Suppose a store owner pays $225 for a suit, and then marks it up $75, to $300. Find the percent increase in price. 4. Compare your answer to Problem 3 above with the problem given in Example 4 of your text. Do you think it is generally true that a 1 25% discount is equivalent to a 33% markup? 3

Answer 4. $82.50; $467.50 5. $40.16

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5.5 Problem Set

371

Problem Set 5.5 A

B Solve each of these problems using the method developed in this section. [Examples 1–3]

1. Salary Increase If a person earns $23,000 a year and gets a 7% increase in salary, what is the new salary?

2. Salary Increase A computer programmer’s yearly income of $57,000 is increased by 8%. What is the dollar amount of the increase, and what is her new salary?

3. Tuition Increase The yearly tuition at a college is

4. Price Increase A market increased the price of cheese

presently $6,000. Next year it is expected to increase by

selling for $4.98 per pound by 3%. What is the new price

17%. What will the tuition at this school be next year?

for a pound of cheese? (Round to the nearest cent.)

5. Car Value In one year a new car decreased in value by

6. Calorie Content A certain light beer has 20% fewer calo-

20%. If it sold for $16,500 when it was new, what was it

ries than the regular beer. If the regular beer has 120

worth after 1 year?

calories per bottle, how many calories are in the samesized bottle of the light beer?

7. Salary Increase A person earning $3,500 a month gets a

8. Rate Increase A student reader is making $6.50 per hour

raise of $350 per month. What is the percent increase

and gets a $0.70 raise. What is the percent increase?

in salary?

(Round to the nearest tenth of a percent.)

9. Shoe Sale Shoes that usually sell for $25 are on sale for $20. What is the percent decrease in price?

10. Enrollment Decrease The enrollment in a certain elementary school was 410 in 2007. In 2008, the enrollment in the same school was 328. Find the percent decrease in enrollment from 2007 to 2008.

11. Students to Teachers The chart shows the student to

12. Health Care The graph shows the rising cost of health

teacher ratio in the United States from 1975 to 2002.

care. What is the percent increase in health care costs

What is the percent decrease in student to teacher ratio

from 2002 to 2014?

from 1975 to 2002? Round to the nearest percent.

Student Per Teacher Ratio In the U.S.

Health Care Costs on the Rise

20.4

1985

17.9

1995 2002

17.8 16.2

Billions of Dollars

4000 1975

2,399.2 2400 1,559.0

1,936.5

1600 800 0

Source: nces.ed.gov

3,585.7 2,944.2

3200

2002

2005

2008

2011

Source: Centers for Medicare and Medicaid Services

2014

372

Chapter 5 Percent

C [Examples 4, 5] 13. Discount During a clearance sale, a three-piece suit that

14. Sale Price On opening day, a new music store offers a

usually sells for $300 is marked “15% off.” What is the

12% discount on all electric guitars. If the regular price

discount? What is the sale price?

on a guitar is $550, what is the sale price?

15. Total Price A man buys a washing machine that is on

16. Total Price A bedroom set that normally sells for $1,450

sale. The washing machine usually sells for $450 but is

is on sale for 10% off. If the sales tax rate is 5%, what is

on sale at 20% off. If the sales tax rate in his state is 6%,

the total price of the bedroom set if it is bought while

how much is the total bill for the washer?

on sale?

17. Real Estate Market In 2006 the average price of a home

18. Deep Discount When buying some of today’s newest

began to fall in most real estate markets across the

electronic gadgets, good things come to those who

country. The median price of a single family home in

wait. When Apple released its new iPhone in the sum-

the U.S. was $227,000 in 2006. The median price is

mer of 2007, an 8GB model sold for $499. In July 2008,

now $195,500. By what percent did the median price of

Apple released its new iPhone 3G. The 8GB model sells

a single family home drop? Round your answer to the

for $199. What is the percent decrease in price for this

nearest tenth of a percent.

new model? Round your answer to the nearest tenth of a percent.

19. Losing Weight According to the Centers for Disease

20. Ordering Online You are in the market for a new laptop.

Control and Prevention (CDC), more than 60% of U.S.

The model that you wish to purchase is $1,500 in a

adults are overweight, and about 15% of children and

local store. However, you decide to buy the computer

adolescents ages 6 to 19 are overweight. Your friend

over the Internet for $1200. You will need to pay ship-

decides to go on a diet and goes from 155 pounds to

ping charges of $59 plus the 6% local sales tax. Taking

130 pounds over a 4 month period. What was her per-

into account taxes and shipping charges, what percent-

centage weight loss? Round your answer to the nearest

age do you save by ordering it online? Round your an-

percent.

swer to the nearest tenth of a percent.

21. Product Error When manufacturing a product, a certain

22. Home Remodeling You have decided to update your

amount of variation (or error) can occur in the process

house by laying a new wood floor in your living room.

and still create a part or product that is useable. For

Your floor has an area of 440 sq ft. You decide to buy

one particular company, a 3% error is acceptable for

enough flooring to allow for a certain amount of waste

their machine parts to be used safely. If the part they

so you purchase 470 sq ft of wood flooring materials.

are manufacturing is 22.5 in. long, what is the range of

Express your waste allowance as a percent. Round

measures that are acceptable for this part?

your result to the nearest percent.

5.5 Problem Set

373

Calculator Problems Set up the following problems the same way you set up Problems 1–22. Then use a calculator to do the calculations.

23. Salary Increase A teacher making $43,752 per year gets

24. Utility Increase A homeowner had a $95.90 electric bill

a 6.5% raise. What is the new salary?

in December. In January the bill was $107.40. Find the percent increase in the electric bill from December to January. (Round to the nearest whole number.)

25. Soccer The rules for soccer state that the playing field must be from 100 to 120 yards long and 55 to 75 yards wide. The 1999 Women’s World Cup was played at the Rose Bowl on a playing field 116 yards long and 72 yards wide. The diagram below shows the smallest possible soccer field, the largest possible soccer field, and the soccer field at the Rose Bowl.

Soccer Fields 120 yd

116 yd 100 yd 72 yd

75 yd

55 yd

Smallest

Rose Bowl

Largest

a. Percent Increase A team plays on the smallest field, then plays in the Rose Bowl. What is the percent increase in the area of the playing field from the smallest field to the Rose Bowl? Round to the nearest tenth of a percent.

b. Percent Increase A team plays a soccer game in the Rose Bowl. The next game is on a field with the largest dimensions. What is the percent increase in the area of the playing field from the Rose Bowl to the largest field? Round to the nearest tenth of a percent.

26. Football The diagrams below show the dimensions of playing fields for the National Football League (NFL), the Canadian Football League (CFL), and Arena Football.

Football Fields 110 yd 100 yd

65 yd

53 13 yd

50yd 28 13 yd

NFL

Canadian

Arena

a. Percent Increase In 1999 Kurt Warner made a successful transition from Arena Football to the NFL, winning the Most Valuable Player award. What was the percent increase in the area of the fields he played on in moving from Arena Football to the NFL? Round to the nearest percent.

b. Percent Decrease Doug Flutie played in the Canadian Football League before moving to the NFL. What was the percent decrease in the area of the fields he played on in moving from the CFL to the NFL? Round to the nearest tenth of a percent.

374

Chapter 5 Percent

Getting Ready for the Next Section Multiply. Round to nearest hundredth if necessary.

27. 0.07(2,000)

1

6

29. 600(0.04) 

28. 0.12(8,000)

1

1

4

1

4

30. 900(0.06) 

4

31. 10,150(0.06) 

32. 10,302.25(0.06) 

33. 3,210  224.7

34. 900  13.50

35. 10,000 150

36. 10,150  152.25

37. 10,302.25  154.53

38. 10,456.78  156.85

Add.

Simplify.

39. 2,000  0.07(2,000)

40. 8,000  0.12(8,000)

41. 3,000  0.07(3,000)

42. 9,000  0.12(9,000)

Maintaining Your Skills The problems below review some basic concepts of addition of fractions and mixed numbers. Add each of the following and reduce all answers to lowest terms. 1 3

2 3

43.   

3 4

2 3

47.   

3 8

1 8

45.   

3 8

1 6

49. 2   3 

44.   

48.   

1 2

1 2

1 4

1 5

3 10

46.   

1 2

1 4

1 8

50. 3   2 

Interest Anyone who has borrowed money from a bank or other lending institution, or who has invested money in a savings account, is aware of interest. Interest is the amount of money paid for the use of money. If we put $500 in a savings account

5.6 Objectives A Solve simple interest problems. B Solve compound interest problems.

that pays 6% annually, the interest will be 6% of $500, or 0.06(500)  $30. The amount we invest ($500) is called the principal, the percent (6%) is the interest rate, and the money earned ($30) is the interest.

EXAMPLE 1

Examples now playing at

MathTV.com/books A man invests $2,000 in a savings plan that pays 7% per

year. How much money will be in the account at the end of 1 year?

SOLUTION

PRACTICE PROBLEMS

We first find the interest by taking 7% of the principal, $2,000:

1. A man invests $3,000 in a savings plan that pays 8% per year. How much money will be in the account at the end of 1 year?

Interest  0.07($2,000)  $140 The interest earned in 1 year is $140. The total amount of money in the account at the end of a year is the original amount plus the $140 interest: $2,000 

140 $2,140

Original investment (principal) Interest (7% of $2,000) Amount after 1 year

The amount in the account after 1 year is $2,140.

EXAMPLE 2

A farmer borrows $8,000 from his local bank at 12%. How

much does he pay back to the bank at the end of the year to pay off the loan?

SOLUTION

The interest he pays on the $8,000 is Interest  0.12($8,000)

2. If a woman borrows $7,500 from her local bank at 12% interest, how much does she pay back to the bank if she pays off the loan in 1 year?

 $960 At the end of the year, he must pay back the original amount he borrowed ($8,000) plus the interest at 12%: $8,000 

960 $8,960

Amount borrowed (principal) Interest at 12% Total amount to pay back

The total amount that the farmer pays back is $8,960.

A Simple Interest There are many situations in which interest on a loan is figured on other than a yearly basis. Many short-term loans are for only 30 or 60 days. In these cases we can use a formula to calculate the interest that has accumulated. This type of interest is called simple interest. The formula is IPRT where I  Interest P  Principal R  Interest rate (this is the percent)

Answers 1. $3,240 2. $8,400

T  Time (in years, 1 year  360 days)

5.6 Interest

375

376

Chapter 5 Percent We could have used this formula to find the interest in Examples 1 and 2. In those two cases, T is 1. When the length of time is in days rather than years, it is common practice to use 360 days for 1 year, and we write T as a fraction. Examples 3 and 4 illustrate this procedure.

3. Another student takes out a loan like the one in Example 3. This loan is for $700 at 4%. How much interest does this student pay if the loan is paid back in 90 days?

EXAMPLE 3

A student takes out an emergency loan for tuition, books,

and supplies. The loan is for $600 at an interest rate of 4%. How much interest does the student pay if the loan is paid back in 60 days? The principal P is $600, the rate R is 4%  0.04, and the time T is 60 60  . Notice that T must be given in years, and 60 days   year. Applying the 360 360 formula, we have

SOLUTION

IPRT 60 I  600  0.04   360 1 I  600  0.04   6

1 60    6 360

I4

Multiplication

The interest is $4.

4. Suppose $1,200 is deposited in an account that pays 9.5% interest per year. If all the money is withdrawn after 120 days, how much money is withdrawn?

EXAMPLE 4

A woman deposits $900 in an account that pays 6% annu-

ally. If she withdraws all the money in the account after 90 days, how much does she withdraw? 90 We have P  $900, R  0.06, and T  90 days   year. Using 360 these numbers in the formula, we have

SOLUTION

IPRT 90 I  900  0.06   360 1 I  900  0.06   4

1 90    360 4

I  13.5

Multiplication

The interest earned in 90 days is $13.50. If the woman withdraws all the money in her account, she will withdraw $900.00 Original amount (principal) 

13.50 Interest for 90 days $913.50 Total amount withdrawn

The woman will withdraw $913.50.

B Compound Interest A second common kind of interest is compound interest. Compound interest includes interest paid on interest. We can use what we know about simple interest to help us solve problems involving compound interest. 5. If $5,000 is put into an account that pays 6% compounded annually, how much money is in the account at the end of 2 years?

EXAMPLE 5 2 years?

SOLUTION Answers 3. $7 4. $1,238

A homemaker puts $3,000 into a savings account that

pays 7% compounded annually. How much money is in the account at the end of

Because the account pays 7% annually, the simple interest at the

end of 1 year is 7% of $3,000:

377

5.6 Interest Interest after 1 year  0.07($3,000)  $210 Because the interest is paid annually, at the end of 1 year the total amount of money in the account is $3,000 

210 $3,210

Original amount Interest for 1 year Total in account after 1 year

The interest paid for the second year is 7% of this new total, or

Note

If the interest earned in Example 5 were calculated using the formula for simple interest, I  P  R  T, the amount of money in the account at the end of two years would be $3,420.00.

Interest paid the second year  0.07($3,210)  $224.70 At the end of 2 years, the total in the account is $3,210.00 

224.70 $3,434.70

Amount at the beginning of year 2 Interest paid for year 2 Account after 2 years

At the end of 2 years, the account totals $3,434.70. The total interest earned during this 2-year period is $210 (first year)  $224.70 (second year)  $434.70.

You may have heard of savings and loan companies that offer interest rates that are compounded quarterly. If the interest rate is, say, 6% and it is com1

pounded quarterly, then after every 90 days (4 of a year) the interest is added to the account. If it is compounded semiannually, then the interest is added to the account every 6 months. Most accounts have interest rates that are compounded daily, which means the simple interest is computed daily and added to the account.

EXAMPLE 6

If $10,000 is invested in a savings account that pays 6%

compounded quarterly, how much is in the account at the end of a year?

SOLUTION

1

The interest for the first quarter (4 of a year) is calculated using the

formula for simple interest:

6. If $20,000 is invested in an account that pays 8% compounded quarterly, how much is in the account at the end of a year?

IPRT 1 I  $10,000  0.06   4

First quarter

I  $150 At the end of the first quarter, this interest is added to the original principal. The new principal is $10,000  $150  $10,150. Again we apply the formula to calculate the interest for the second quarter: 1 I  $10,150  0.06   4

Second quarter

I  $152.25 The principal at the end of the second quarter is $10,150  $152.25  $10,302.25. The interest earned during the third quarter is 1 I  $10,302.25  0.06   4

Third quarter

I  $154.53

To the nearest cent

Answer 5. $5,618

378

Chapter 5 Percent The new principal is $10,302.25  $154.53  $10,456.78. Interest for the fourth quarter is 1 I  $10,456.78  0.06   4

Fourth quarter

I  $156.85

To the nearest cent

The total amount of money in this account at the end of 1 year is $10,456.78  $156.85  $10,613.63

USING

TECHNOLOGY

Compound Interest from a Formula We can summarize the work above with a formula that allows us to calculate compound interest for any interest rate and any number of compounding periods. If we invest P dollars at an annual interest rate r, compounded n times a year, then the amount of money in the account after t years is given by the formula



r AP 1  n



nt

Using numbers from Example 6 to illustrate, we have P  Principal  $10,000 r  annual interest rate  0.06 n  number of compounding periods  4 (interest is compounded quarterly) t  number of years  1 Substituting these numbers into the formula above, we have



0.06 A  10,000 1   4

Note

The reason that this answer is different from the result we obtained in Example 6 is that, in Example 6, we rounded each calculation as we did it. The calculator will keep all the digits in all of the intermediate calculations.



41

 10,000(1  0.015)4  10,000(1.015)4 To simplify this last expression on a calculator, we have

Scientific calculator: 10,000  1.015 yx 4  Graphing calculator: 10,000  1.015 ^ 4 ENTER In either case, the answer is $10,613.63551, which rounds to $10,613.64.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Suppose the man in Example 1 invested $3,000, instead of $2,000, in the savings plan. How much more interest would he have earned? 2. How much does the student in Example 3 pay back if the loan is paid off after a year, instead of after 60 days?

Answer 6. $21,648.64

3. Suppose the homemaker mentioned in Example 5 invests $3,000 in an 1 account that pays only 3% compounded annually. How much is in the 2 account at the end of 2 years? 4. In Example 6, how much money would the account contain at the end of 1 year if it were compounded annually, instead of quarterly?

5.6 Problem Set

379

Problem Set 5.6 A These problems are similar to the examples found in this section. They should be set up and solved in the same way. (Problems 1–12 involve simple interest.) [Examples 1–4]

1. Savings Account A man invests $2,000 in a savings plan that pays 8% per year. How much money will be in the

2. Savings Account How much simple interest is earned on $5,000 if it is invested for 1 year at 5%?

account at the end of 1 year?

3. Savings Account A savings account pays 7% per year.

4. Savings Account A local bank pays 5.5% annual interest

How much interest will $9,500 invested in such an

on all savings accounts. If $600 is invested in this type

account earn in a year?

of account, how much will be in the account at the end of a year?

5. Bank Loan A farmer borrows $8,000 from his local bank at 7%. How much does he pay back to the bank at the

6. Bank Loan If $400 is borrowed at a rate of 12% for 1 year, how much is the interest?

end of the year when he pays off the loan?

7. Bank Loan A bank lends one of its customers $2,000 at

8. Bank Loan If a loan of $2,000 at 20% for 1 year is to be

8% for 1 year. If the customer pays the loan back at the

paid back in one payment at the end of the year, how

end of the year, how much does he pay the bank?

much does the borrower pay the bank?

9. Student Loan A student takes out an emergency loan for tuition, books, and supplies. The loan is for $600 with

10. Short-Term Loan If a loan of $1,200 at 9% is paid off in 90 days, what is the interest?

an annual interest rate of 5%. How much interest does the student pay if the loan is paid back in 60 days?

11. Savings Account A woman deposits $800 in a savings

12. Savings Account $1,800 is deposited in a savings ac-

account that pays 5%. If she withdraws all the money in

count that pays 6%. If the money is withdrawn at the

the account after 120 days, how much does she with-

end of 30 days, how much interest is earned?

draw?

380

Chapter 5 Percent

B The problems that follow involve compound interest. [Examples 5, 6] Compound Interest The chart shows the interest rates for various CD accounts. 13. Last year Samuel invested $400 in a 6-month CD. If the interest is compounded quarterly, how much was in the account at the end

Latest CD Yields (%)

compounded quarterly. Use the compound interest formula and round to the nearest cent.

6-month

1-year

Year ago

5-year

Source: bankrate.com

15. Compound Interest A woman puts $5,000 into a savings

16. Compound Interest A savings account pays 5% com-

account that pays 6% compounded annually. How

pounded annually. If $10,000 is deposited in the

much money is in the account at the end of 2 years?

account, how much is in the account after 2 years?

17. Compound Interest If $8,000 is invested in a savings

4.11

4.67

4.70

21/2-year

Last week

This week

3.34 Year ago

4.48

4.45 Last week

This week

Year ago

3.32

4.64

4.63 This week

Last week

3.16 Year ago

4.29

4.23

what will the account make at the end of its term if interest is

This week

1

14. If Alice deposited $200 in a 22 year CD account earlier this week,

Last week

of 6 months? Round to the nearest cent.

18. Compound Interest Suppose $1,200 is invested in a sav-

account that pays 5% compounded quarterly, how

ings account that pays 6% compounded semiannually.

much is in the account at the end of a year?

How much is in the account at the end of 12 years?

1

Calculator Problems The following problems should be set up in the same way in which Problems 1–18 have been set up. Then the calculations should be done on a calculator.

19. Savings Account A woman invests $917.26 in a savings

20. Business Loan The owner of a clothing store borrows

account that pays 6.25% annually. How much is in the

$6,210 for 1 year at 11.5% interest. If he pays the loan

account at the end of a year?

back at the end of the year, how much does he pay back?

21. Compound Interest Suppose $10,000 is invested in each

22. Compound Interest Suppose $5,000 is invested in each

account below. In each case find the amount of money

account below. In each case find the amount of money

in the account at the end of 5 years.

in the account at the end of 10 years.

a. Annual interest rate  6%, compounded quarterly

a. Annual interest rate  5%, compounded quarterly

b. Annual interest rate  6%, compounded monthly

b. Annual interest rate  6%, compounded quarterly

c. Annual interest rate  5%, compounded quarterly

c. Annual interest rate  7%, compounded quarterly

d. Annual interest rate  5%, compounded monthly

d. Annual interest rate  8%, compounded quarterly

5.6 Problem Set

Getting Ready for the Next Section Change to percent. 75 250

150 250

23. 

400 2,400

200 2,400

24. 

25. 

26. 

28. 0.4(360)

29. 0.45(360)

30. 0.15(360)

32. 45  5

33. 15  5

34. 5  5

Multiply.

27. 0.3(360)

Divide.

31. 40  5

Maintaining Your Skills The problems below will allow you to review subtraction of fractions and mixed numbers. 3 4

9 10

1 4

35.   

4 3

40. 2  

1 4

9 12

43.   

8 35

1 5

1 2

42. 1  

1 6

1 4

45. 3   2

8 35

1 4

46. 5   3 

8 35

48. Find the difference of  and .

49. Find the product of  and .

1 5

38.   

8 15

47. Find the sum of  and . 8 15

7 10

1 4

41. 1  

44.   

8 15

5 8

37.   

1 2

4 3

39. 2  

1 3

7 10

36.   

8 15

8 35

50. Find the quotient of  and .

381

382

Chapter 5 Percent

Extending the Concepts The following problems are percent problems. Use any of the methods developed in this chapter to solve them.

51. Credit Card Debt Student credit-card debt is at an all-

52. Finding Your Interest Rate In early January, your bank

time high. Consolidated Credit Counseling Services Inc.

sent out a form called a 1099-INT, which summarizes

reports that 20% of all college freshman got their first

the amount of interest you have received on a savings

credit card in high school and nearly 40% sign up for

account for the previous year. If you received $72 inter-

one in their first year at college. Suppose your credit

est for the year on an account in which you started

card company charges 1.3% in finance charges per

with $1,200, determine the annual interest rate paid by

month on the average daily balance in your credit card

your bank.

account. If your average daily balance for this month is $2,367.90 determine the finance charge for the month.

53. Movie Making The bar chart below shows the production costs for each of the first four Star Wars movies. Find the percent increase in production costs from each Star Wars movie to the next. Round your results to the nearest tenth. 115

100 80 60 32.5

40

Douglas Kirkland/Corbis

The Phantom Menace 1999

Return of the Jedi 1983

0

11

18

The Empire Strikes Back 1980

20

Star Wars 1977

Production costs (millions of dollars)

120

54. Movie Making The table below shows how much money each of the first four Star Wars movies brought in during the first weekend they were shown. Find the percent increase in opening weekend income from each Star Wars movie to the next. Round to the nearest percent.

Opening Weekend Income Star Wars (1977) The Empire Strikes Back (1980) Return of the Jedi (1983) The Phantom Menace (1999)

$1,554,000 $6,415,000 $30,490,000 $64,810,000

Pie Charts Pie charts are another way in which to visualize numerical information. They lend themselves well to information that adds up to 100% and are very common in the world around us. In fact, it is hard to pick up a newspaper or magazine without

5.7 Objectives A Read a pie chart. B Construct a pie chart.

seeing a pie chart. As the diagram below shows, even a computer will represent the amount of free space and used space on one of its disks by using a pie chart.

Examples now playing at

MathTV.com/books

A Reading a Pie Chart Some of this introductory material will be review. We want to begin our study of pie charts by reading information from pie charts.

PRACTICE PROBLEMS

EXAMPLE 1

The pie chart shows the class rank of the members of a

drama club. Use the pie chart to answer the following questions.

a. Find the total membership of the club. b. Find the ratio of freshmen to total number of members. c. Find the ratio of seniors to juniors. SOLUTION

a. To find the total membership in the club, we add the numbers in

1. Work Example 1 again if one more junior joins the club.

Seniors 9

Freshmen 11

Juniors 15

Sophomores 10

all sections of the pie chart. 9  11  15  10  45 members

b. The ratio of freshmen to total members is 11 number of freshmen    total number of members 45

c. The ratio of seniors to juniors is 9 number of seniors 3      number of juniors 15 5

Answer 11 9 1. a. 46 b.  c.  46

5.7 Pie Charts

16

383

384

Chapter 5 Percent

2. Work Example 2 again if 600 people responded to the survey.

EXAMPLE 2

The pie chart shows the results of a survey on how often

people check their e-mail. Use the pie chart to answer the following questions. Suppose 500 people participated in the survey.

a. How many people in the survey check their e-mail daily? b. How many people check their e-mail once a week or less often?

Time Spent Checking E-mail 76% Daily 1% Less than once a week

SOLUTION

a. To find out how many people in the survey check their e-mail

23% Weekly

daily, we need to find 76% of 500. 0.76(500)  380 of the people surveyed check their e-mail daily

b. The people checking their e-mail weekly or less often account for 23%  1%  24%. To find out how many of the 500 people are in this category, we must find 24% of 500.

Source: UCLA Center for Communication Policy

0.24(500)  120 of the people surveyed check their e-mail weekly or less often

B Constructing Pie Charts EXAMPLE 3 shows the used space and free space on a 256-MB flash memory stick that contains 102 MB of data.

Construct a pie chart that shows the free space and used

space for a 256-MB flash memory stick that contains 77 MB of data.

EDGE Tech Corp

3. Construct a pie chart that

SOLUTION 1

Using a Template

As mentioned previously, pie charts are con-

structed with percents. Therefore we must first convert data to percents. To find the percent of used space, we divide the amount of used space by the amount of total space. We have 77   0.30078 which is 30% to the nearest percent 256 The area of each section of the template on the left is 5% of the area of the whole

PIE CHART TEMPLATE Each slice is 5% of the area of the circle.

circle. If we shade 6 sections of the template, we will have shaded 30% of the area of the whole circle.

6

5 4 3 2 1

Answer 2. a. 456 people b. 144 people

PIE CHART TEMPLATE Each slice is 5% of the area of the circle.

CREATING A PIE CHART To shade 30% of the circle, we shade 6 sections of the template.

385

5.7 Pie Charts The shaded area represents 30%, which is the amount of used disk space. The rest of the circle must represent the 70% free space on the disk. Shading each area with a different color and labeling each, we have our pie chart.

Used space 30%

Free space 70%

FIGURE 1

SOLUTION 2

Using a Protractor

Since a pie chart is a circle, and a circle

contains 360°, we must now convert our data to degrees. We do this by multiplying our percents in decimal form by 360. We have (0.30)360°  108° Now we place a protractor on top of a circle. First we draw a line from the center of the circle to 0° as shown in Figure 2. Now we measure and mark 108° from our starting point, as shown in Figure 3.

2

3

4

1

5

CM

2

6

7

8

9

10 170 1 20 3 60 15 0 4 0 14 0 0

1

MADE IN CHINA

0

10

4

5

1

2

MADE IN CHINA

E L EM ENT S

3

80 90 100 70 100 90 80 110 1 70 2 60 0 110 60 0 1 2 3 1 0 5 0 50 0 13

6



1

2

3

4

5

CM

6

7

8

9

170 160 0 20 10 15 0 30 14 0 4

0

80 90 100 70 100 90 80 110 1 70 2 60 0 110 60 0 1 2 3 1 0 5 0 50 0 13

170 160 0 20 10 15 0 30 14 0 4

10 170 1 20 3 60 15 0 4 0 14 0 0

108°

10

E L EM ENT S

3

4

5

6



FIGURE 3

FIGURE 2

Finally we draw a line from the center of the circle to this mark, as shown in Figure 4. Then we shade and label the two regions as shown in Figure 5.

108°

Used space 30%



Free space 70%

FIGURE 4

FIGURE 5

Answer 3. See solutions section.

386

Chapter 5 Percent

4. The table below shows how the expenses for a paperback novel are divided. Use the information in the table to construct a pie chart.

Expense Bookstore Publisher Author

EXAMPLE 4

Construct a pie chart from the information in the following

table. WHERE DOES YOUR TEXTBOOK MONEY GO? Expense Bookstore Publisher Author

Percent of Price 45% 50% 5%

Percent of Price

SOLUTION

40% 45% 15%

Since our template uses sections that each represent 5% of the cir-

cle, we shade 8 sections, representing 40%, for the bookstore’s share. Then we shade 9 sections, representing 45% for the publisher’s share. We should have 3 sections remaining, which represent the 15% share going to the author.

8

7

6

5 1

4 2

3 2

3

1

4 5

3 6

2 7

PIE CHART TEMPLATE Each slice is 5% of the area of the circle.

CREATING A PIE CHART

8

1

9

To shade 45% of the circle, we shade 9 sections of the template.

We are left with 3 sections. This represents the 15% share going to the author.

We label each section with the appropriate information, and our pie chart is complete.

Bookstore 40%

Publisher 45%

Author 15%

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. If a circle is divided into 20 equal slices, then each of the slices is what percent of the total area enclosed by the circle? 2. If a 250 MB computer drive contains 75 MB of data, then how much of the drive is free space? 3. If a 250 MB computer drive contains 75 MB of data, then what percent of the drive contains data? Answer 4. See solutions section.

4. Explain how you would construct a pie chart of monthly expenses for a person who spends $700 on rent, $200 on food, and $100 on entertainment.

5.7 Problem Set

387

Problem Set 5.7 A [Examples 1, 2] 1. High School Seniors with Jobs The pie chart shows the results of surveying 200 high school seniors to find out how many hours they worked per week at a job.

a. Find the ratio of students who work more than 15 hours a

High School Seniors with Jobs

week to total students. 76

82

More than 15 Hours 15 Hours or Less

b. Find the ratio of students who don’t have a job to students 42

who work more than 15 hours a week.

Didn’t Work

c. Find the ratio of students with jobs to total students.

d. Find the ratio of students with jobs to students without jobs.

2. Favorite Dip Flavor The pie chart shows the results of a survey on favorite dip flavor. a. What is the most preferred dip flavor? Favorite Dip Flavor b. Which dip flavor is preferred second most? 7%

c. Which dip flavor is least preferred?

37%

Ranch 56%

Dill Onion

d. What percentage of people preferred ranch? e. What percentage of people preferred onion or dill? f.

If 50 people responded to the survey, how many people preferred ranch?

g. If 50 people responded to the survey, how many people preferred dill? (Round your answer to the nearest whole number.)

3. Food Dropped on the Floor The pie chart shows the results of a survey about eating food that has been dropped on the floor. Participants were asked whether they eat food that has been on the floor for 3, 5, or 10 seconds.

a. What percentage of people say it is not safe to eat food

Food Dropped On the Floor

dropped on the floor?

b. What percentage of people believe the “three-second rule”? c. What percentage of people will eat food that stays on the floor for five seconds or less?

d. What percentage of people will eat foot that stays on the floor for ten seconds or less?

10%

8% 4%

Not Safe 78%

3-second Rule 5-second Rule 10-second Rule

388

Chapter 5 Percent

4. Talking to Our Dogs A survey showed that most dog owners talk to their dogs. a. What percentage of dog owners say they never talk to their

Talking To Our Dogs

dogs?

1% 5%

b. What percentage of dog owners say they talk to their dogs all the time?

All the time

23%

Sometimes 71%

c. What percentage of dog owners say they talk to their dogs

Not often Never

sometimes or not often?

5. Monthly Car Payments Suppose 3,000 people responded to a survey on car loan payments, the results of which are shown in the pie chart. Find the number of people whose monthly payments would be the following:

Monthly Car Payments

a. $700 or more Less than $300

17%

b. Less than $300

8%

43%

$300-$499 $600-$699

32%

c. $500 or more

$700 or more

d. $300 to $699

6. Where Workers Say Germs Lurk A survey asked workers where they thought the most germ-contaminated spot in the workplace was. Suppose the survey took place at a large company with 4,200 employees. Use the pie chart to determine the number of employees who would vote for each of the following as the most germ-contaminated areas.

a. Keyboards

Where Workers Say Germs Lurk b. Doorknobs 17%

c. Restrooms or other d. Telephones or doorknobs

10% 6% 3%

35%

29%

Doorknobs Telephones Restrooms Keyboards Other Don’t know

5.7 Problem Set

B [Examples 3, 4] 7. Grade Distribution Student scores, for a class of 20, on a recent math test are shown in the table below. Construct a pie chart that shows the number of As, Bs, and Cs earned on the test. Use the template provided here or use a protractor. GRADE DISTRIBUTION Grade

Number

A B C

5 8 7

Total

20

PIE CHART TEMPLATE Each slice is 5% of the area of the circle.

8. Building Sizes The Lean and Mean Gym Company recently ran a promotion for their four locations in the county. The table shows the locations along with the amount of square feet at each location. Use the information in the table to construct a pie chart, using the template provided here or using a protractor. GYM LOCATION AND SIZE Square Feet

Location Downtown Uptown Lakeside Mall

35,000 85,000 25,000 75,000

Total

PIE CHART TEMPLATE Each slice is 5% of the area of the circle.

220,000

9. Room Sizes Scott and Amy are building their dream house. The size of the house will be 2,400 square feet. The table below shows the size of each room. Use the information in the table to construct a pie chart, using the template provided here or using a protractor.

ROOM SIZES Room Kitchen Dining room Bedrooms Living room Bathrooms Total

Square Feet 400 310 890 600 200 2,400

PIE CHART TEMPLATE Each slice is 5% of the area of the circle.

389

390

Chapter 5 Percent

10. Airline Seating The table below gives the number of seats in each of the three classes of seating on an American Airlines Boeing 777 airliner. Create a pie chart from the information in the table.

AIRLINE SEATING Seating Class

Number Of Seats

First Business Coach

18 42 163

PIE CHART TEMPLATE Each slice is 5% of the area of the circle.

Maintaining Your Skills Multiply. 1 3

1 3

11. 8  

1 1,000

12. 9  

1 100

15. 36.5    10

1 12

1 3

19. 48    

1 100

13. 25  

1 1,000

16. 36.5    100

1 12

1 2

20. 56    

1 10

14. 25  

1 10

17. 248    

1 10

1 10

18. 969    

Chapter 5 Summary The Meaning of Percent [5.1] EXAMPLES Percent means “per hundred.” It is a way of comparing numbers to the number 100.

1. 42% means 42 per hundred or 42 . 100

Changing Percents to Decimals [5.1] To change a percent to a decimal, drop the percent symbol (%), and move the

2. 75%  0.75

decimal point two places to the left.

Changing Decimals to Percents [5.1] To change a decimal to a percent, move the decimal point two places to the right,

3. 0.25  25%

and use the % symbol.

Changing Percents to Fractions [5.1] To change a percent to a fraction, drop the % symbol, and use a denominator of

6 3  4. 6%   100  50

100. Reduce the resulting fraction to lowest terms if necessary.

Changing Fractions to Percents [5.1] To change a fraction to a percent, either write the fraction as a decimal and then change the decimal to a percent, or write the fraction as an equivalent fraction with denominator 100, drop the 100, and use the % symbol.

3 5.  4  0.75  75%

or 9 90     90% 10 100

Basic Word Problems Involving Percents [5.2] There are three basic types of word problems:

6. Translating to equations, we have: Type A: n  0.14(68) Type B: 75n  25 Type C: 25  0.40n

Type A: What number is 14% of 68? Type B: What percent of 75 is 25? Type C: 25 is 40% of what number? To solve them, we write is as , of as  (multiply), and what number or what percent as n. We then solve the resulting equation to find the answer to the original question.

Chapter 5

Summary

391

392

Chapter 5 Percent

Applications of Percent [5.3, 5.4, 5.5, 5.6] There are many different kinds of application problems involving percent. They include problems on income tax, sales tax, commission, discount, percent increase and decrease, and interest. Generally, to solve these problems, we restate them as an equivalent problem of Type A, B, or C from the previous page. Problems involving simple interest can be solved using the formula IPRT where I  interest, P  principal, R  interest rate, and T  time (in years). It is standard procedure with simple interest problems to use 360 days  1 year.

Pie Charts [5.7] A pie chart is another way to give a visual representation of the information in a table.

Seating Class

Number Of Seats

First Business Coach

18 42 163

First 8%

Business 19%

Coach 73%

COMMON MISTAKES 1. A common mistake is forgetting to change a percent to a decimal when working problems that involve percents in the calculations. We always change percents to decimals before doing any calculations.

2. Moving the decimal point in the wrong direction when converting percents to decimals or decimals to percents is another common mistake. Remember, percent means “per hundred.” Rewriting a number expressed as a percent as a decimal will make the numerical part smaller. 25%  0.25

Chapter 5

Review

Write each percent as a decimal. [5.1]

1. 35%

2. 17.8%

3. 5%

4. 0.2%

7. 0.495

8. 1.65

Write each decimal as a percent. [5.1]

5. 0.95

6. 0.8

Write each percent as a fraction or mixed number in lowest terms. [5.1]

9. 75%

10. 4%

11. 145%

12. 2.5%

Write each fraction or mixed number as a percent. [5.1] 3 10

13. 

5 8

14. 

3 4

2 3

15. 

16. 4 

Solve the following problems. [5.2]

17. What number is 60% of 28?

18. What number is 122% of 55?

19. What percent of 38 is 19?

20. What percent of 19 is 38?

21. 24 is 30% of what number?

22. 16 is 8% of what number?

23. Survey Suppose 45 out of 60 people surveyed believe a

24. Discount A lawnmower that usually sells for $175 is marked down to $140. What is the discount? What is

tential. What percent believe this? [5.3]

the discount rate? [5.5]

SALE

college education will increase a person’s earning po-

POWER MOWER REGULARLY $175

$140.00

SALE PRICE

Chapter 5

Review

393

394

Chapter 5 Percent

25. Total Price A sewing machine that normally sells for

26. Home Mortgage If the interest rate on a home mortgage

$600 is on sale for 25% off. If the sales tax rate is 6%,

is 9%, then each month you pay 0.75% of the unpaid

what is the total price of the sewing machine if it is

balance in interest. If the unpaid balance on one such

purchased during the sale? [5.4, 5.5]

loan is $60,000 at the beginning of a month, how much interest must be paid that month? [5.6]

27. Percent Increase At the beginning of the summer, the

28. Percent Decrease A gallon of regular gasoline is selling

price for a gallon of regular gasoline is $4.25. By the

for $1.45 in September. If the price decreases 14% in

end of summer, the price has increased 16%. What is

October, what is the new price for a gallon of regular

the new price of a gallon of regular gasoline? Round to

gasoline? Round to the nearest cent. [5.5]

the nearest cent. [5.5]

GAS PRICES

JUNE

21

REGULAR

UNLEADED U SUPER

$4.25

AUGUST

30

$4.30

GAS PRICES

REGULAR

U UNLEADED SUPER

$4.35

$? $4.51 $4.57

29. Medical Costs The table shows the average yearly cost

30. Commission A real estate agent gets a commission of

of visits to the doctor, as reported in USA Today. What

6% on all houses he sells. If his total sales for Decem-

is the percent increase in cost from 1990 to 2000?

ber are $420,000, how much money does he make?

Round to the nearest tenth of a percent. [5.5]

[5.4]

MEDICAL COSTS Year

Average Annual Cost

1990 1995 2000 2005

$583 $739 $906 $1,172

31. Discount A washing machine that usually sells for $300

32. Total Price A tennis racket that normally sells for $240

is marked down to $240. What is the discount? What is

is on sale for 25% off. If the sales tax rate is 5%, what is

the discount rate? [5.5]

the total price of the tennis racket if it is purchased

WASHING MACHINE REGULARLY $300

SALE PRICE

$240.00

SALE

SALE

during the sale? [5.4]

TENNIS RACKET REGULARLY $240

SALE DISCOUNT

25% OFF

Chapter 5

Cumulative Review

Simplify:

1. 6,801

2.

4. 1,023  15

3. 52(867)

5,038  2,769

539  374

7 8

9. 5  3.678

3 8

5 8

6.   

5. 4.731 5 6 .0 9 

7.

10. 1.2(0.21)

7 12

1 5

13.   

7 10

14. 8   5 

3 8

 6  5

3

7 15

8. 4.551  3.08

5 14

8 27

11.   

20 63

12.   

2 3

15. 9  4 

1 2

1 4

16. Subtract 5  from 10.375.

17. Find the quotient of 1  and  .

18. Translate into symbols, and then simplify: Twice the

19. Write the ratio of 3 to 12 as a fraction in lowest terms.

sum of 2 and 9.

20. If 1 mile is 5,280 feet, how many feet are there in 2.5

21. If 1 square yard is 1,296 square inches, how many 1 square inches are in  square yard? 2

miles?

1 8

22. Write  as a percent.

2 x

23. Convert 46% to a fraction.

5 8

24. Solve the equation   

25. 3  52  2  42  5  23

26. What number is 5% of 32?

27. 55 is what percent of 275?

Chapter 5

Cumulative Review

395

396

Chapter 5 Percent

28. 8.8 is 15% of what number?

29. Unit Pricing If a six-pack of Coke costs $2.79, what is the price per can to the nearest cent?

four 1-cup servings. If the quart costs $1.61, find the

5(F  32) 9 temperature in degrees Celsius when the Fahrenheit

price per serving to the nearest cent.

temperature is 212°F.

30. Unit Pricing A quart of 2% reduced-fat milk contains

32. Savings Account Laura invests $500 in an account that

31. Temperature Use the formula C   to find the

33. Percent Increase Kendra is earning $1600 a month when

pays 8% interest each year. How much does she have in

she receives a raise to $1800 a month. What is the per-

the account after 2 years?

cent increase in her monthly salary?

34. Driving Distance If Ethan drives his car 230 miles in 4 hours, how far will he drive in 6 hours if he drives at

35. Number Problem The product of 6 and 8 is how much larger than the sum of 6 and 8?

the same rate?

36. Movie Tickets A movie theater has a total of 250 seats. If they have a sellout crowd for a matinee and each ticket

37. Geometry Find the perimeter and area of a square with side 8.5 inches.

costs $7.25, how much money will ticket sales bring in that afternoon?

38. Average If a basketball team has scores of 64, 76, 98,

39. Hourly Pay Jean tutors in the math lab and earns $56 in

55, and 102 in their first five games, find the mean

one week. If she works 8 hours that week, what is her

score.

hourly pay?

Chapter 5

Test

Write each percent as a decimal.

1. 18%

2. 4%

3. 0.5%

5. 0.7

6. 1.35

Write each decimal as a percent.

4. 0.45

Write each percent as a fraction or a mixed number in lowest terms.

7. 65%

8. 146%

9. 3.5%

Write each number as a percent.

7 20

10. 

13. What number is 75% of 60?

3 8

11. 

3 4

12. 1 

14. What percent of 40 is 18?

15. 16 is 20% of what number?

Chapter 5

Test

397

398

Chapter 5 Percent

16. Driver’s Test On a 25-question driver’s test, a student

17. Commission A salesperson gets an 8% commission rate

answered 23 questions correctly. What percent of the

on all computers she sells. If she sells $12,000 in com-

questions did the student answer correctly?

puters in 1 day, what is her commission?

18. Discount A washing machine that usually sells for $250

19. Total Price A tennis racket that normally sells for $280

is marked down to $210. What is the discount? What is

is on sale for 25% off. If the sales tax rate is 5%, what is

the discount rate?

the total price of the tennis racket if it is purchased

WASHING MACHINE REGULARLY $250

SALE PRICE

$210.00

20. Simple Interest If $5,000 is invested at 8% simple interest for 3 months, how much interest is earned?

SALE

SALE

during the sale?

TENNIS RACKET REGULARLY $280

SALE DISCOUNT

25% OFF

21. Compound Interest How much interest will be earned on a savings account that pays 10% compounded annually, if $12,000 is invested for 2 years?

Chapter 5 Projects PERCENTS

GROUP PROJECT Group Project Number of People Time Needed Equipment Background

2 5 minutes Pencil, paper, and calculator. All of us spend time buying clothes and eating meals at restaurants. In all of these situations, it is good practice to check receipts. This project is intended to give you practice creating receipts of your own.

Procedure

Fill in the missing parts of each receipt.

SALES RECEIPT

SALES RECEIPT Jeans

29.99

2 Buffet Dinners @ 9.99

Sales Tax (7.75%)

Discount (10%)

Total

Total

SALES RECEIPT Computer

19.98

SALES RECEIPT 400.00

Couch

Discount: 30% off

Sales Tax (7%)

Discounted Price

Total

588.50

Sales Tax (6%) Total

Chapter 5

Projects

399

RESEARCH PROJECT Credit-Card Debt Credit-card companies are now offering creditcards to college students who would not be able to get a card under normal credit-card criteria (due to lack of credit history and low income). The credit-card industry sees young people as a valuable market because research shows that they remain loyal to their first cards as they grow older. Nellie Mae, the student loan agency, found that 78% of college students had credit cards in 2000. For many of these students, lack of financial experience or education leads to serious debt. According to Nellie Mae, undergraduates with credit-cards carried an average balance of $2,748 in 2000. Half of their balances in full every month. Choose a credit-card and find out the minimum monthly payment and the APR (annual percentage rate). Compute the minimum monthly payment and interest charges for a balance of $2,748.

400

Chapter 5 Percent

Stockbyte/SuperStock

credit-card-carrying college students don’t pay

A Glimpse of Algebra There is really no direct extension of percent to algebra. Because that is the case, we will go back to some of the algebraic expressions we have encountered previously and evaluate them. To evaluate an expression, such as 5x  4, when we know that x is 7, we simply substitute 7 for x in the expression 5x  4 and then simplify the result. When

x7

the expression

5x  4

becomes

5(7)  4

or

35  4  39

Here are some examples.

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

Find the value of the expression 4x  3x  8 when x is 2.

Substituting 2 for x in the expression, we have:

1. Find the value of the expression 6x  3x  10 when x is 3.

4(2)  3(2)  8  8  6  8  14  8 6 We say that 4x  3x  8 becomes 6 when x is 2.

EXAMPLE 2

Find the value of the following expression when a is 5:

expression when a is 10:

4a  8  3a  8

SOLUTION

2. Find the value of the following 4a  20  5a  20

Replacing a with 5 in the expression, we have: 4(5)  8 20  8    3(5)  8 15  8 28   7 4

EXAMPLE 3 SOLUTION

Find the value of x 2  5x  6 when x is 4.

3. Find the value of x2  6x  8 when x is 3.

When x is 4, the expression x 2  5x  6 becomes (4)2  5(4)  6  16  20  6  42

Answers 1. 17 2. 2 3. 35

A Glimpse of Algebra

401

402

4. Find the value of the following expression when x is 10 and y is 4: 3x  y  3x  y

Chapter 5 Percent

EXAMPLE 4 SOLUTION

4x  y Find the value of  when x is 5 and y is 2: 4x  y

This time we have two different variables. We replace x with 5 and

y with 2 to get 4(5)  2 20  2    4(5)  2 20  2 22   18 11   9

5. Find the value of (4x  1)(4x  1) when x is 2.

EXAMPLE 5 SOLUTION

Find the value of (2x  3)(2x  3) when x is 4.

Replacing x with 4 in the expression, we have: (2  4  3)(2  4  3)  (8  3)(8  3)  (11)(5)  55

6. Find the value of the following expression when x is 5. x3  8  x2

EXAMPLE 6 SOLUTION

x3  8 Find the value of  when x is 5: x2

We substitute 5 for x and then simplify: 53  8 125  8    52 3 117   3  39

Answers 17 13

4.  5. 63 6. 19

A Glimpse of Algebra Problems

A Glimpse of Algebra Problems Find the value of each of the following expressions for the given values of the variables.

1. 6x  2x  7 when x is 2

2. 8x  10x  5 when x is 3

3. 4x  6x  8x when x is 10

4. 9x  2x  20x when x is 5

4a  20 5a  20

5. 

when a is 5

2a  3a  1 4a  5a  3

7. 

when a is 3

9. x 2  5x  6 when x is 2

11. x 2  10x  25 when x is 1

3x  y 3x  y

13. 

when x is 5 and y is 2

4a  8 3a  8

6. 

when a is 8

7a  a  4 6a  2a  3

8. 

when a is 10

10. x 2  6x  8 when x is 6

12. x 2  10x  25 when x is 0

5x  y 5x  y

14. 

when x is 10 and y is 5

403

404

Chapter 5 Percent

15.

when x is 5 and y is 4

8x  3y 3x  8y

16. 

when x is 5 and y is 10

17. (3x  2)(3x  2) when x is 4

18. (5x  4)(5x  4) when x is 2

19. (2x  3)2 when x is 1

20. (2x  3)3 when x is 2

x3  1 x1

21. 

when x is 2

x3  8 x  2x  4

23.  2

x 4  16 x 4

25.  2

when x is 3

when x is 5

x3  1 x1

22. 

when x is 4

x3  8 x  2x  4

24.  2

x 4  16 x 2

26. 

when x is 3

when x is 3

6

Measurement

Chapter Outline 6.1 Unit Analysis I: Length 6.2 Unit Analysis II: Area and Volume 6.3 Unit Analysis III: Weight 6.4 Converting Between the Two Systems and Temperature 6.5 Operations with Time and Mixed Units

Introduction The Google Earth image here shows the Nile River in Africa. The Nile is the longest river in the world, measuring 4,160 miles and stretching across ten different countries. Rivers across the world serve as important means of transportation, particularly in less developed countries, like those in Africa.

Nile River English Units

Metric Units

Length

4,160 mi

6,695 km

Nile Delta Area

1,004 mi²

36,000 km²

Flow Rate (monsoon season)

285,829 ft³/s

8,100 m³/s

Average Summer Temperature 86°F

30°C Source: http://www.worldwildlife.org

In this chapter we look at the process we use to convert from one set of units, such as miles per hour, to another set of units, such as kilometers per hour. You will be interested to know that regardless of the units in question, the method we use is the same in all cases. The method is called unit analysis and it is the foundation of this chapter.

405

Chapter Pretest The pretest below contains problems that are representative of the problems you will find in the chapter. Make the following conversions.

1. 8 ft to inches

2. 90 in. to yards

3. 32 m to centimeters

4. 61 mm to centimeters

5. 30 yd2 to square feet

6. 432 in2 to square feet

7. 3,840 acres to square miles

8. 1.4 m2 to square centimeters

9. 3 gallons to quarts

10. 72 pints to gallons

11. 251 mL to liters

12. 4 lb to ounces

13. 2,142 mg to grams

14. 9 m to yards

15. 3 gal to liters

16. 104°F to degrees Celsius

17. The speed limit on a certain

18. If meat costs $3.05 per pound,

road is 45 miles/hour. Convert

how much will 2 lb 4 oz cost?

this to feet/second.

Getting Ready for Chapter 6 The problems below review material covered previously that you need to know in order to be successful in Chapter 6. If you have any difficulty with the problems here, you need to go back and review before going on to Chapter 6. Write each of the following ratios as a fraction in lowest terms.

1. 12 to 30

2. 5,280 to 1,320

Simplify.

3. 12  16

4. 50  250

5. 75  43,560

6. 100  3  12

7. 2.49  3.75

8. 5  28  1.36

1 3

1 1000

9. 8   12. 256  640

11.  36.5  10 100

80.5 1.61

13. 

14. 

1100  60  60 5280

16. 10  

2  1000 16.39

18.  (Round to the nearest tenth.)

15.  17.  (Round to the nearest whole number.)

12 16

19. Convert  to a decimal.

406

1800 4

10. 25  

Chapter 6 Measurement

12 5

5(102  32) 9

20. Find the perimeter and area of a 24 in.  36 in. poster.

Unit Analysis I: Length Introduction . . . In this section we will become more familiar with the units used to measure length. We will look at the U.S. system of measurement and the metric system of measurement.

A U.S. Units of Length

6.1 A

Convert between lengths in the U.S. system.

B

Convert between lengths in the metric system.

C

Solve application problems involving unit analysis.

Measuring the length of an object is done by assigning a number to its length. To let other people know what that number represents, we include with it a unit of measure. The most common units used to represent length in the U.S. system are

Examples now playing at

inches, feet, yards, and miles. The basic unit of length is the foot. The other units

MathTV.com/books

are defined in terms of feet, as Table 1 shows.

TABLE 1 12 inches (in.)  1 foot (ft) 1 yard (yd)  3 feet 1 mile (mi)  5,280 feet

1 foot 0

1

2

3

4

5

6

7

8

9

10

11

12

As you can see from the table, the abbreviations for inches, feet, yards, and miles are in., ft, yd, and mi, respectively. What we haven’t indicated, even though you may not have realized it, is what 1 foot represents. We have defined all our units associated with length in terms of feet, but we haven’t said what a foot is. There is a long history of the evolution of what is now called a foot. At different times in the past, a foot has represented different arbitrary lengths. Currently, a foot is defined to be exactly 0.3048 meter (the basic measure of length in the metric system), where a meter is 1,650,763.73 wavelengths of the orange-red line in the spectrum of krypton-86 in a vacuum (this doesn’t mean much to me either). The reason a foot and a meter are defined this way is that we always want them to measure the same length. Because the wavelength of the orange-red line in the spectrum of krypton-86 will always remain the same, so will the length that a foot represents. Now that we have said what we mean by 1 foot (even though we may not understand the technical definition), we can go on and look at some examples that involve converting from one kind of unit to another.

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

1. Convert 8 feet to inches.

Convert 5 feet to inches.

Because 1 foot  12 inches, we can multiply 5 by 12 inches to get 5 feet  5  12 inches  60 inches

This method of converting from feet to inches probably seems fairly simple. But as we go further in this chapter, the conversions from one kind of unit to another will become more complicated. For these more complicated problems, we need another way to show conversions so that we can be certain to end them with the correct unit of measure. For example, since 1 ft  12 in., we can say that there are 12 in. per 1 ft or 1 ft per 12 in. That is: 12 in.  m888Per 1 ft

or

1 ft  m888 Per 12 in.

Answer 1. 96 in.

6.1 Unit Analysis I: Length

407

408

Chapter 6 Measurement

1 ft 12 in. We call the expressions  and  conversion factors. The fraction bar is 1 ft 12 in. read as “per.” Both these conversion factors are really just the number 1. That is: 12 in. 12 in.    1 1 ft 12 in. We already know that multiplying a number by 1 leaves the number unchanged. So, to convert from one unit to the other, we can multiply by one of the conversion factors without changing value. Both the conversion factors above say the same thing about the units feet and inches. They both indicate that there are 12 inches in every foot. The one we choose to multiply by depends on what units we are starting with and what units we want to end up with. If we start with feet and we want to end up with inches, we multiply by the conversion factor 12 in.  1 ft The units of feet will divide out and leave us with inches. 12 in.    5 feet  5 ft 1 ft  5  12 in.  60 in. The key to this method of conversion lies in setting the problem up so that the

Note

We will use this method of converting from one kind of unit to another throughout the rest of this chapter. You should practice using it until you are comfortable with it and can use it correctly. However, it is not the only method of converting units. You may see shortcuts that will allow you to get results more quickly. Use shortcuts if you wish, so long as you can consistently get correct answers and are not using your shortcuts because you don’t understand our method of conversion. Use the method of conversion as given here until you are good at it; then use shortcuts if you want to.

2. The roof of a two-story house is 26 feet above the ground. How many yards is this?

correct units divide out to simplify the expression. We are treating units such as feet in the same way we treated factors when reducing fractions. If a factor is common to the numerator and the denominator, we can divide it out and simplify the fraction. The same idea holds for units such as feet. We can rewrite Table 1 so that it shows the conversion factors associated with units of length, as shown in Table 2. TABLE 2

UNITS OF LENGTH IN THE U.S. SYSTEM The Relationship Between

Is

To Convert From One To The Other, Multiply By

feet and inches

12 in.  1 ft

12 in.  1 ft

or

1 ft  12 in.

feet and yards

1 yd  3 ft

3 ft  1 yd

or

1 yd  3 ft

feet and miles

1 mi  5,280 ft

5,280 ft  1 mi

or

1 mi  5,280 ft

EXAMPLE 2

The most common ceiling height in houses is 8 feet. How

many yards is this?

8 ft

409

6.1 Unit Analysis I: Length

SOLUTION

To convert 8 feet to yards, we multiply by the conversion factor 1 yd  so that feet will divide out and we will be left with yards. 3 ft 1 yd   8 ft  8 ft 3 ft 8   yd 3

1 3

8 3

8   

2

 23 yd

EXAMPLE 3

Multiply by correct conversion factor

Or 2.67 yd to the nearest hundredth

A football field is 100 yards long. How many inches long is

3. How many inches are in 220 yards?

a football field? 100 yd

SOLUTION

In this example we must convert yards to feet and then feet to

inches. (To make this example more interesting, we are pretending we don’t know that there are 36 inches in a yard.) We choose the conversion factors that will allow all the units except inches to divide out. 3 ft 12 in. 100 yd  100  yd     1 yd 1 ft  100  3  12 in.  3,600 in.

B Metric Units of Length In the metric system the standard unit of length is a meter. A meter is a little longer than a yard (about 3.4 inches longer). The other units of length in the metric system are written in terms of a meter. The metric system uses prefixes to indicate what part of the basic unit of measure is being used. For example, in millimeter the prefix milli means “one thousandth” of a meter. Table 3 gives the meanings of the most common metric prefixes.

TABLE 3

THE MEANING OF METRIC PREFIXES Prefix milli centi deci deka hecto kilo

Meaning 0.001 0.01 0.1 10 100 1,000

We can use these prefixes to write the other units of length and conversion factors for the metric system, as given in Table 4.

Answers 2

2. 8  3 yd, or 8.67 yd 3. 7,920 in.

410

Chapter 6 Measurement

TABLE 4

METRIC UNITS OF LENGTH The Relationship Between

To Convert From One To The Other, Multiply By

Is

millimeters (mm) and meters (m)

1,000 mm  1 m

1,000 mm  1m

or

1m  1,000 mm

centimeters (cm) and meters

100 cm  1 m

100 cm  1m

or

1m  100 cm

decimeters (dm) and meters

10 dm  1 m

10 dm  1m

or

1m  10 dm

dekameters (dam) and meters

1 dam  10 m

10 m  1 dam

or

1 dam  10 m

100 m  1 hm

or

1 hm  100 m

1,000 m  1 km

or

1 km  1,000 m

hectometers (hm) and meters

1 hm  100 m

kilometers (km) and meters

1 km  1,000 m

We use the same method to convert between units in the metric system as we did with the U.S. system. We choose the conversion factor that will allow the units we start with to divide out, leaving the units we want to end up with.

4. Convert 67 centimeters to meters.

EXAMPLE 4

Convert 25 millimeters to meters.

SOLUTION

To convert from millimeters to meters, we multiply by the conver1m sion factor  : 1,000 mm 1m 25 mm  25  mm   1,000  mm 25 m   1,000  0.025 m

5. Convert 78.4 mm to decimeters.

EXAMPLE 5 SOLUTION

Convert 36.5 centimeters to decimeters.

We convert centimeters to meters and then meters to decimeters: 10 dm 1 m 36.5 cm  36.5  cm     100  cm 1 m 36.5  10   dm 100  3.65 dm

The most common units of length in the metric system are millimeters, centimeters, meters, and kilometers. The other units of length we have listed in our table of metric lengths are not as widely used. The method we have used to convert from one unit of length to another in Examples 2–5 is called unit analysis. If you take a chemistry class, you will see it used many times. The same is true of many other science classes as well.

Answers 4. 0.67 m 5. 0.784 dm

411

6.1 Unit Analysis I: Length We can summarize the procedure used in unit analysis with the following steps:

Strategy Unit Analysis Step 1: Identify the units you are starting with. Step 2: Identify the units you want to end with. Step 3: Find conversion factors that will bridge the starting units and the ending units.

Step 4: Set up the multiplication problem so that all units except the units you want to end with will divide out.

C Applications EXAMPLE 6

A sheep rancher is making new lambing pens for the

upcoming lambing season. Each pen is a rectangle 6 feet wide and 8 feet long. The fencing material he wants to use sells for $1.36 per foot. If he is planning to build five separate lambing pens (they are separate because he wants a walkway between them), how much will he have to spend for fencing material?

SOLUTION

6. The rancher in Example 6 decides to build six pens instead of five and upgrades his fencing material so that it costs $1.72 per foot. How much does it cost him to build the six pens?

To find the amount of fencing material he needs for one pen, we find

the perimeter of a pen.

6 ft 8 ft Perimeter  6  6  8  8  28 feet We set up the solution to the problem using unit analysis. Our starting unit is pens and our ending unit is dollars. Here are the conversion factors that will form a bridge between pens and dollars: 1 pen  28 feet of fencing 1 foot of fencing  1.36 dollars Next we write the multiplication problem, using the conversion factors, that will allow all the units except dollars to divide out: 28 feet of fencing 1.36 dollars      5 pens  5 pens 1 pen 1 foot of fencing  5  28  1.36 dollars  $190.40

Answer 6. $288.96

412

Chapter 6 Measurement

7. Assume that the mistake in the advertisement is that feet per second should read feet per minute. Is 1,100 feet per minute a reasonable speed for a chair lift?

EXAMPLE 7

A number of years ago, a ski resort in Vermont advertised

their new high-speed chair lift as “the world’s fastest chair lift, with a speed of 1,100 feet per second.” Show why the speed cannot be correct.

SOLUTION

To solve this problem, we can convert feet per second into miles per

hour, a unit of measure we are more familiar with on an intuitive level. Here are the conversion factors we will use: 1 mile  5,280 feet 1 hour  60 minutes

sec

0 ft/

1,10

WORLD’S

FASTEST CHAIRLIFT

1 minute  60 seconds 60 minutes 1,100 feet 1 mile 60 seconds 1,100 ft/second         1 second 5,280 feet 1 minute 1 hour 1,100  60  60 miles   5,280 hours  750 miles/hour

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Write the relationship between feet and miles. That is, write an equality that shows how many feet are in every mile. 2. Give the metric prefix that means “one hundredth.” 3. Give the metric prefix that is equivalent to 1,000. 4. As you know from reading the section in the text, conversion factors are ratios. Write the conversion factor that will allow you to convert from inches to feet. That is, if we wanted to convert 27 inches to feet, what conversion factor would we use?

Answer 7. 12.5 mi/hr is a reasonable speed for a chair lift.

6.1 Problem Set

413

Problem Set 6.1 A Make the following conversions in the U.S. system by multiplying by the appropriate conversion factor. Write your answers as whole numbers or mixed numbers. [Examples 1–3]

1. 5 ft to inches

2. 9 ft to inches

3. 10 ft to inches

4. 20 ft to inches

5. 2 yd to feet

6. 8 yd to feet

7. 4.5 yd to inches

8. 9.5 yd to inches

9. 27 in. to feet

13. 48 in. to yards

10. 36 in. to feet

11. 2.5 mi to feet

12. 6.75 mi to feet

14. 56 in. to yards

B Make the following conversions in the metric system by multiplying by the appropriate conversion factor. Write your answers as whole numbers or decimals. [Examples 4, 5]

15. 18 m to centimeters

16. 18 m to millimeters

17. 4.8 km to meters

18. 8.9 km to meters

19. 5 dm to centimeters

20. 12 dm to millimeters

21. 248 m to kilometers

22. 969 m to kilometers

23. 67 cm to millimeters

24. 67 mm to centimeters

25. 3,498 cm to meters

26. 4,388 dm to meters

27. 63.4 cm to decimeters

28. 89.5 cm to decimeters

414

C

Chapter 6 Measurement

Applying the Concepts

[Examples 6, 7]

29. Mountains The map shows the heights of the tallest mountains in the world. According to the map, K2 is

30. Classroom Energy The chart shows how much energy is wasted in the classroom by leaving appliances on.

28,238 ft. Convert this to miles. Round to the nearest tenth of a mile.

Energy Estimates All units given as watts per hour. Ceiling fan Stereo Television VCR/DVD player

The Greatest Heights K2 28,238 ft Mount Everest 29,035 ft Kangchenjunga 28,208 ft PAKISTAN

NEP AL

Printer Photocopier Coffee maker

125 400 130 20 400 400 1000 Source: dosomething.org 2008

CHINA

Convert the the wattage of the following appliances to

INDIA Source: Forrester Research, 2005

kilowatts.

a. Ceiling fan b. VCR/DVD player c. Coffee maker

32. Notebook Width

between first and sec-

Standard-sized

ond base in softball is

notebook paper is

60 feet, how many

21.6 centimeters

yards is it from first to

wide. Express this

ft

second base?

60

31. Softball If the distance

33. High Jump If a person high jumps 6 feet 8 inches, how many inches is the jump?

35. Ceiling Height Suppose the ceiling of a home is 2.44 meters above the floor. Express the height of the ceiling

21.6 cm

width in millimeters.

34. Desk Width A desk is 48 inches wide. What is the width in yards?

36. Tower Height A transmitting tower is 100 feet tall. How many inches is that?

in centimeters.

37. Surveying A unit of measure sometimes used in survey-

38. Surveying Another unit of measure used in surveying is

ing is the chain. There are 80 chains in 1 mile. How

a link; 1 link is about 8 inches. About how many links

many chains are in 37 miles?

are there in 5 feet?

39. Metric System A very small unit of measure in the met-

40. Metric System Another very small unit of measure in the

ric system is the micron (abbreviated ␮m). There are

metric system is the angstrom (abbreviated Å). There

1,000 ␮m in 1 millimeter. How many microns are in

are 10,000,000 Å in 1 millimeter. How many angstroms

12 centimeters?

are in 15 decimeters?

6.1 Problem Set 41. Horse Racing In horse racing, 1 furlong is 220 yards.

415

42. Speed of a Bullet A bullet from a machine gun on a B-17

How many feet are in 12 furlongs?

Flying Fortress in World War II had a muzzle speed of 1,750 feet/second. Convert 1,750 feet/second to miles/hour. (Round to the nearest whole number.)

Turf course Main track

Finish

43. Speed Limit The maximum speed limit on part of

Courtesy of the U.S. Air Force Museum

7 furlongs

44. Speed Limit The maximum speed limit on part of

Highway 101 in California is 55 miles/hour. Convert

Highway 5 in California is 65 miles/hour. Convert

55 miles/hour to feet/second. (Round to the nearest

65 miles/hour to feet/second. (Round to the nearest

tenth.)

tenth.)

45. Track and Field A person who runs the 100-yard dash in

46. Track and Field A person who runs a mile in 8 minutes

10.5 seconds has an average speed of 9.52

has an average speed of 0.125 miles/minute. Convert

yards/second. Convert 9.52 yards/second to

0.125 miles/minute to miles/hour.

miles/hour. (Round to the nearest tenth.)

47. Speed of a Bullet The bullet from a rifle leaves the barrel traveling 1,500 feet/second. Convert 1,500 feet/second

48. Sailing A fathom is 6 feet. How many yards are in 19 fathoms?

to miles/hour. (Round to the nearest whole number.)

Calculator Problems Set up the following conversions as you have been doing. Then perform the calculations on a calculator.

49. Change 751 miles to feet.

50. Change 639.87 centimeters to meters.

51. Change 4,982 yards to inches.

52. Change 379 millimeters to kilometers.

53. Mount Whitney is the highest point in California. It is

54. The tallest mountain in the United States is Mount

14,494 feet above sea level. Give its height in miles to

McKinley in Alaska. It is 20,320 feet tall. Give its height

the nearest tenth.

in miles to the nearest tenth.

55. California has 3,427 miles of shoreline. How many feet is this?

56. The tip of the TV tower at the top of the Empire State Building in New York City is 1,472 feet above the ground. Express this height in miles to the nearest hundredth.

416

Chapter 6 Measurement

Getting Ready for the Next Section Perform the indicated operations.

57. 12  12

58. 36  24

59. 1  4  2

60. 5  4  2

61. 10  10  10

62. 100  100  100

63. 75  43,560

64. 55  43,560

65. 864  144

66. 1,728  144

67. 256  640

68. 960  240

9 1

9 1

1 4

1 10

1 4

69. 45  

70. 36  

71. 1,800  

72. 2,000    

73. 1.5  30

74. 1.5  45

75. 2.2  1,000

76. 3.5  1,000

77. 67.5  9

78. 43.5  9

Maintaining Your Skills Write your answers as whole numbers, proper fractions, or mixed numbers. Find each product. (Multiply.) 2 3

1 2

79.   

7 9

3 14

80.   

3 4

81. 8  

1 2

1 3

1 6

1 3

83. 1   2 

84.   4

1 3

89. 1   2 

3 4

90.   1 

82. 12  

2 3

Find each quotient. (Divide.) 3 4

1 8

85.   

3 5

6 25

86.   

2 3

87. 4  

88. 1  

1 2

9 8

7 8

Extending the Concepts 91. Fitness Walking The guidelines for fitness now indicate that a person who walks 10,000 steps daily is physically fit. According to The Walking Site on the Internet, “The average person’s stride length is approximately 2.5 feet long. That means it takes just over 2,000 steps to walk one mile, and 10,000 steps is close to 5 miles.” Use your knowledge of unit analysis to determine if these facts are correct.

Unit Analysis II: Area and Volume Figure 1 below gives a summary of the geometric objects we have worked with in previous chapters, along with the formulas for finding the area of each object.

w

s

l Area  (length)(width) A  lw

s Area  (side)(side)  (side)2 A  s2

6.2 Objectives A Convert between areas using the U.S. system.

B

Convert between areas using the metric system.

C

Convert between volumes using the U.S. system.

D

Convert between volumes using the metric system.

Examples now playing at

MathTV.com/books

h

b Area  12 (base)(height) A  12 bh FIGURE 1 Areas of common geometric shapes

A Conversion Factors in the U.S. System EXAMPLE 1 SOLUTION

PRACTICE PROBLEMS Find the number of square inches in 1 square foot.

We can think of 1 square foot as 1 ft2  1 ft  ft. To convert from feet

1. Find the number of square feet in 1 square yard.

to inches, we use the conversion factor 1 foot  12 inches. Because the unit foot appears twice in 1 ft2, we multiply by our conversion factor twice. 12 in. 12 in. 1 ft2  1  ft   ft      12  12 in.  in.  144 in2 1 ft 1 ft

Now that we know that 1 ft2 is the same as 144 in2, we can use this fact as a conversion factor to convert between square feet and square inches. Depending on which units we are converting from, we would use either 144 in2  1 ft2

or

1 ft2 2 144 in

Answer 1. 1 yd2  9 ft2

6.2 Unit Analysis II: Area and Volume

417

418

2. If the poster in Example 2 is surrounded by a frame 6 inches wide, find the number of square feet of wall space covered by the framed poster.

Chapter 6 Measurement

EXAMPLE 2

A rectangular poster measures 36 inches by 24 inches.

How many square feet of wall space will the poster cover?

SOLUTION

One way to work this problem is to find the number of square

inches the poster covers, and then convert square inches to square feet. Area of poster  length  width  36 in.  24 in.  864 in2

1 ft2 864 in2  864  in2  2 144  in 864   ft2 144  6 ft2

Image: BigStockPhoto.com © Devanne Philippe

To finish the problem, we convert square inches to square feet:

36”

24”

Table 1 gives the most common units of area in the U.S. system of measurement, along with the corresponding conversion factors.

TABLE 1

U.S. UNITS OF AREA The Relationship Between square inches and square feet square yards and square feet

bolt of material that is 1.5 yards wide and 45 yards long. How many square feet of material were ordered?

9 ft2  1 yd2

640 acres  1 mi2

acres and square miles

EXAMPLE 3

144 in2  1 ft2

1 acre  43,560 ft2

acres and square feet

3. The same dressmaker orders a

Is

144 in2  1 ft2

or

1 ft2  144 in2

9 ft2  1 yd2

or

1 yd2  9 ft2

43,560 ft2  1 acre

or

1 acre  43,560 ft2

640 acres  1 mi2

or

1 mi2  640 acres

A dressmaker orders a bolt of material that is 1.5 yards

wide and 30 yards long. How many square feet of material were ordered?

SOLUTION

The area of the material in square yards is A  1.5  30  45 yd2

Converting this to square feet, we have 9 ft2 45 yd2  45  yd2  2 1 yd  405 ft2

Answers 2. 12 ft2 3. 607.5 ft2

To Convert From One To The Other, Multiply By

419

6.2 Unit Analysis II: Area and Volume

EXAMPLE 4

A farmer has 75 acres of land. How many square feet of

How many square feet of land does the farmer have?

land does the farmer have?

SOLUTION

4. A farmer has 55 acres of land.

Changing acres to square feet, we have 43,560 ft2 75 acres  75 acres    1 acre   75  43,560 ft2  3,267,000 ft2

FOR SALE 75 ACRES FARMLAND

EXAMPLE 5

A new shopping center is to be constructed on 256 acres

SOLUTION

5. A school is to be constructed on 960 acres of land. How many square miles is this?

of land. How many square miles is this? Multiplying by the conversion factor that will allow acres to divide

out, we have 1 mi2    256 acres  256 acres 640 acres  256   mi2 640  0.4 mi2

B Area: The Metric System Units of area in the metric system are considerably simpler than those in the U.S. system because metric units are given in terms of powers of 10. Table 2 lists the conversion factors that are most commonly used. TABLE 2

METRIC UNITS OF AREA The Relationship Between

Is

To Convert From One To The Other, Multiply By

square millimeters and square centimeters

1 cm2  100 mm2

100 mm2  1 cm2

or

1 cm2  100 mm2

square centimeters and square decimeters

1 dm2  100 cm2

100 cm2  1 dm2

or

1 dm2  100 cm2

1 m2  100 dm2

100 dm2  1 m2

or

1 m2  100 dm2

100 m2  1a

or

1a  100 m2

100 a  1 ha

or

1 ha  100 a

square decimeters and square meters square meters and ares (a) ares and hectares (ha)

1 a  100 m2

1 ha  100 a

Answers 4. 2,395,800 ft2 5. 1.5 mi2

420

6. How many square centimeters are in 1 square meter?

Chapter 6 Measurement

EXAMPLE 6 SOLUTION

How many square millimeters are in 1 square meter?

We start with 1 m2 and end up with square millimeters: 100  dm2 100  cm2 100 mm2 1 m2  1  m2       2 2 1 m 1 dm 1 cm2  100  100  100 mm2  1,000,000 mm2

C Volume: The U.S. System Table 3 lists the units of volume in the U.S. system and their conversion factors.

TABLE 3

UNITS OF VOLUME IN THE U.S. SYSTEM The Relationship Between

Is

cubic inches (in3) and cubic feet (ft3)

1 ft3  1,728 in3

cubic feet and cubic yards (yd3)

5-gallon pail?

1,728 in3  1 ft3 27 ft3  1 yd3

1 yd3  27 ft3

or

1 yd3 or 3 27 ft

16 fl oz 1 pt  or   1 pt 16 fl oz

1 pt  16 fl oz

pints and quarts (qt)

1 qt  2 pt

2 pt 1 qt  or  1 qt 2 pt

1 gal  4 qt

4 qt 1 gal  or  1 gal 4 qt

EXAMPLE 7

What is the capacity (volume) in pints of a 1-gallon con-

tainer of milk?

SOLUTION

We change from gallons to quarts and then quarts to pints by multi-

plying by the appropriate conversion factors as given in Table 3. t 2 pt 4q      1 gal  1 gal 1 qt 1g  al  1  4  2 pt  8 pt

ne Gallon

tamin A & added D

A 1-gallon container has the same capacity as 8 one-pint containers.

Answers 6. 10,000 cm2 7. 40 pt

1 ft3  1,728 in3

fluid ounces (fl oz) and pints (pt)

quarts and gallons (gal)

7. How many pints are in a

To Convert From One To The Other, Multiply By

421

6.2 Unit Analysis II: Area and Volume

EXAMPLE 8

A dairy herd produces 1,800 quarts of milk each day. How

quarts of milk each day. How many 10-gallon containers will this milk fill?

many gallons is this equivalent to?

SOLUTION

8. A dairy herd produces 2,000

Converting 1,800 quarts to gallons, we have 1 gal 1,800 qt  1,800  qt   4q t 1,800   gal 4  450 gal

We see that 1,800 quarts is equivalent to 450 gallons.

D Volume: The Metric System In the metric system the basic unit of measure for volume is the liter. A liter is the volume enclosed by a cube that is 10 cm on each edge, as shown in Figure 2. We can see that a liter is equivalent to 1,000 cm3.

10 cm

10 cm

10 cm

1 liter = 10 cm × 10 cm × 10 cm = 1,000 cm3 FIGURE 2 The other units of volume in the metric system use the same prefixes we encountered previously. The units with prefixes centi, deci, and deka are not as common as the others, so in Table 4 we include only liters, milliliters, hectoliters, and kiloliters.

Note

TABLE 4

METRIC UNITS OF VOLUME The Relationship Between

Is

To Convert From One To The Other, Multiply By 1 liter  1,000 mL

milliliters (mL) and liters

1 liter (L)  1,000 mL

1,000 mL  1 liter

hectoliters (hL) and liters

100 liters  1 hL

100 liters 1 hL  or  1 hL 100 liters

kiloliters (kL) and liters

1,000 liters (L)  1 kL

or

1,000 liters  or 1 kL

1 kL  1,000 liters

As you can see from the table and the discussion above, a cubic centimeter (cm3) and a milliliter (mL) are equal. Both are one thousandth of a liter. It is also common in some fields (like medicine) to abbreviate the term cubic centimeter as cc. Although we will use the notation mL when discussing volume in the metric system, you should be aware that 1 mL  1 cm3  1 cc. Answer 8. 50 containers

422

Chapter 6 Measurement Here is an example of conversion from one unit of volume to another in the metric system.

9. A 3.5-liter engine will have a volume of how many milliliters?

EXAMPLE 9

A sports car has a 2.2-liter engine. What is the displace-

ment (volume) of the engine in milliliters?

SOLUTION

Using the appropriate conversion factor from Table 4, we have 1,000 mL 2.2 liters  2.2 liters    1 liter  2.2  1,000 mL  2,200 mL

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Write the formula for the area of each of the following: a. a square of side s. b. a rectangle with length l and width w. 2. What is the relationship between square feet and square inches? 3. Fill in the numerators below so that each conversion factor is equal to 1. qt a.  1 gal

mL b.  1 lit er

ac re s c.  1 m i2

4. Write the conversion factor that will allow us to convert from square yards to square feet.

Answer 9. 3,500 mL

6.2 Problem Set

423

Problem Set 6.2 A Use the tables given in this section to make the following conversions. Be sure to show the conversion factor used in each case. [Examples 1–5]

1. 3 ft2 to square inches

2. 5 ft2 to square inches

3. 288 in2 to square feet

4. 720 in2 to square feet

5. 30 acres to square feet

6. 92 acres to square feet

7. 2 mi2 to acres

8. 7 mi2 to acres

9. 1,920 acres to square miles

11. 12 yd2 to square feet

10. 3,200 acres to square miles

12. 20 yd2 to square feet

B [Example 6] 13. 17 cm2 to square millimeters

14. 150 mm2 to square centimeters

15. 2.8 m2 to square centimeters

16. 10 dm2 to square millimeters

17. 1,200 mm2 to square meters

18. 19.79 cm2 to square meters

19. 5 a to square meters

20. 12 a to square centimeters

21. 7 ha to ares

22. 3.6 ha to ares

23. 342 a to hectares

24. 986 a to hectares

424 C

Chapter 6 Measurement

D Make the following conversions using the conversion factors given in Tables 3 and 4. [Examples 7–9]

25. 5 yd3 to cubic feet

26. 3.8 yd3 to cubic feet

27. 3 pt to fluid ounces

28. 8 pt to fluid ounces

29. 2 gal to quarts

30. 12 gal to quarts

31. 2.5 gal to pints

32. 7 gal to pints

33. 15 qt to fluid ounces

34. 5.9 qt to fluid ounces

35. 64 pt to gallons

36. 256 pt to gallons

37. 12 pt to quarts

38. 18 pt to quarts

39. 243 ft3 to cubic yards

40. 864 ft3 to cubic yards

41. 5 L to milliliters

42. 9.6 L to milliliters

43. 127 mL to liters

44. 93.8 mL to liters

45. 4 kL to milliliters

46. 3 kL to milliliters

47. 14.92 kL to liters

48. 4.71 kL to liters

6.2 Problem Set

425

Applying the Concepts 49. Google Earth The Google Earth map shows Yellowstone

50. Google Earth The Google Earth image shows an aerial

National Park. If the area of the park is roughly 3,402

view of a crop circle found near Wroughton, England. If

square miles, how many acres does the park cover?

the crop circle has a radius of about 59 meters, how many ares does it cover? Round to the nearest are.

51. Swimming Pool A public swimming pool measures 100

52. Construction A family decides to put tiles in the entryway

meters by 30 meters and is rectangular. What is the

of their home. The entryway has an area of 6 square

area of the pool in ares?

meters. If each tile is 5 centimeters by 5 centimeters, how many tiles will it take to cover the entryway?

53. Landscaping A landscaper is putting in a brick patio. The

54. Sewing A dressmaker is using a pattern that requires 2

area of the patio is 110 square meters. If the bricks

square yards of material. If the material is on a bolt that

measure 10 centimeters by 20 centimeters, how many

is 54 inches wide, how long a piece of material must be

bricks will it take to make the patio? Assume no space

cut from the bolt to be sure there is enough material for

between bricks.

the pattern?

55. Filling Coffee Cups If a regular-size coffee cup holds 1

56. Filling Glasses If a regular-size drinking glass holds

about 2 pint, about how many cups can be filled from a

about 0.25 liter of liquid, how many glasses can be

1-gallon coffee maker?

filled from a 750-milliliter container?

57. Capacity of a Refrigerator A refrigerator has a capacity of

58. Volume of a Tank The gasoline tank on a car holds 18

20 cubic feet. What is the capacity of the refrigerator in

gallons of gas. What is the volume of the tank in

cubic inches?

quarts?

59. Filling Glasses How many 8-fluid-ounce glasses of water will it take to fill a 3-gallon aquarium?

60. Filling a Container How many 5-milliliter test tubes filled with water will it take to fill a 1-liter container?

426

Chapter 6 Measurement

Calculator Problems Set up the following problems as you have been doing. Then use a calculator to perform the actual calculations. Round answers to two decimal places where appropriate.

61. Geography Lake Superior is the largest of the Great

62. Geography The state of California consists of 156,360

Lakes. It covers 31,700 square miles of area. What is

square miles of land and 2,330 square miles of water.

the area of Lake Superior in acres?

Write the total area (both land and water) in acres.

63. Geography Death Valley National Monument contains

64. Geography The Badlands National Monument in South

2,067,795 acres of land. How many square miles is

Dakota was established in 1929. It covers 243,302 acres

this?

of land. What is the area in square miles?

65. Convert 93.4 qt to gallons.

66. Convert 7,362 fl oz to gallons.

67. How many cubic feet are contained in 796 cubic yards?

68. The engine of a car has a displacement of 440 cubic inches. What is the displacement in cubic feet?

Getting Ready for the Next Section Perform the indicated operations.

69. 12  16

70. 15  16

71. 3  2,000

72. 5  2,000

73. 3  1,000  100

74. 5  1,000  100

75. 12,500  

1 1,000

1 1,000

76. 15,000  

Maintaining Your Skills The following problems review addition and subtraction with fractions and mixed numbers. 3 8

77.   

1 4

78.   

1 2

1 4

79. 3   5 

7 15

82.   

5 8

1 4

83.   

2 15

81.   

1 2

1 2

80. 6   1 

7 8

5 8

5 36

1 48

84.   

7 39

2 65

Unit Analysis III: Weight A Weights: The U.S. System The most common units of weight in the U.S. system are ounces, pounds, and tons. The relationships among these units are given in Table 1.

6.3 A

Convert between weights using the U.S. system.

B

Convert between weights using the metric system.

TABLE 1

UNITS OF WEIGHT IN THE U.S. SYSTEM The Relationship Between

1 lb  16 oz

ounces (oz) and pounds (lb)

1 T  2,000 lb

pounds and tons (T)

16 oz  1 lb

or

1 lb  16 oz

2,000 lb  1T

or

1T  2,000 lb

Examples now playing at

MathTV.com/books

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

To Convert From One To The Other, Multiply By

Is

1. Convert 15 pounds to ounces.

Convert 12 pounds to ounces.

Using the conversion factor from the table, and applying the method

we have been using, we have 16 oz    12 lb  12 lb 1 lb  12  16 oz  192 oz 12 pounds is equivalent to 192 ounces.

EXAMPLE 2 SOLUTION

2. Convert 5 tons to pounds.

Convert 3 tons to pounds.

We use the conversion factor from the table. We have 2,000 lb 3 T3 T   1 T  6,000 lb

6,000 pounds is the equivalent of 3 tons.

B Weights: The Metric System In the metric system the basic unit of weight is a gram. We use the same prefixes we have already used to write the other units of weight in terms of grams. Table 2 lists the most common metric units of weight and their conversion factors. TABLE 2

METRIC UNITS OF WEIGHT The Relationship Between

Is

milligrams (mg) and grams (g)

1 g  1,000 mg

centigrams (cg) and grams

1 g  100 cg

kilograms (kg) and grams metric tons (t) and kilograms

1,000 g  1 kg 1,000 kg  1 t

To Convert From One To The Other, Multiply By 1,000 mg 1g  or  1,000 mg 1g 1g 100 cg  or  100 cg 1g 1 kg 1,000 g  or  1 kg 1,000 g 1t 1,000 kg  or  1,000 kg 1t

6.3 Unit Analysis III: Weight

Answers 1. 240 oz 2. 10,000 lb

427

428

3. Convert 5 kilograms to milligrams.

Chapter 6 Measurement

EXAMPLE 3 SOLUTION

Convert 3 kilograms to centigrams.

We convert kilograms to grams and then grams to centigrams: 1,000 g  100 cg 3 kg  3 kg      1k g 1g    3  1,000  100 cg  300,000 cg

4. A bottle of vitamin C contains 75 tablets. If each tablet contains 200 milligrams of vitamin C, what is the total number of grams of vitamin C in the bottle?

EXAMPLE 4

A bottle of vitamin C contains 50 tablets. Each tablet con-

tains 250 milligrams of vitamin C. What is the total number of grams of vitamin C in the bottle?

SOLUTION

We begin by finding the total number of milligrams of vitamin C in

the bottle. Since there are 50 tablets, and each contains 250 mg of vitamin C, we can multiply 50 by 250 to get the total number of milligrams of vitamin C: Milligrams of vitamin C  50  250 mg  12,500 mg Next we convert 12,500 mg to grams: 1g 12,500 mg  12,500  mg   1,000  mg 12,500  g 1,000  12.5 g The bottle contains 12.5 g of vitamin C.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. What is the relationship between pounds and ounces? 2. Write the conversion factor used to convert from pounds to ounces. 3. Write the conversion factor used to convert from milligrams to grams. 4. What is the relationship between grams and kilograms?

Answers 3. 5,000,000 mg 4. 15 g

6.3 Problem Set

Problem Set 6.3 A Use the conversion factors in Tables 1 and 2 to make the following conversions. [Examples 1, 2] 1. 8 lb to ounces

2. 5 lb to ounces

3. 2 T to pounds

4. 5 T to pounds

5. 192 oz to pounds

6. 176 oz to pounds

7. 1,800 lb to tons

8. 10,200 lb to tons

9. 1 T to ounces

1 2

12. 5 lb to ounces

14. 4 T to pounds

1 5

15. 2 kg to grams

16. 5 kg to grams

17. 4 cg to milligrams

18. 3 cg to milligrams

19. 2 kg to centigrams

20. 5 kg to centigrams

21. 5.08 g to centigrams

22. 7.14 g to centigrams

23. 450 cg to grams

24. 979 cg to grams

25. 478.95 mg to centigrams

26. 659.43 mg to centigrams

27. 1,578 mg to grams

28. 1,979 mg to grams

29. 42,000 cg to kilograms

30. 97,000 cg to kilograms

10. 3 T to ounces

1 2

13. 6 T to pounds

11. 3 lb to ounces

1 4

B [Examples 3, 4]

429

430

Chapter 6 Measurement

Applying the Concepts 31. Fish Oil A bottle of fish oil contains 60 soft gels, each

32. Fish Oil A bottle of fish oil contains 50

containing 800 mg of the omega-3 fatty acid. How

soft gels, each containing 300 mg of

many total grams of the omega-3 fatty acid are in this

the omega-6 fatty acid. How many

bottle?

total grams of the omega-6 fatty acid are in this bottle?

33. B-Complex A certain B-complex vita-

34. B-Complex A certain B-complex vitamin supplement

min supplement contains 50 mg of

contains 30 mg of thiamine, or vitamin B1. A bottle

riboflavin, or vitamin B2. A bottle con-

contains 80 vitamins. How many total grams of thi-

tains 80 vitamins. How many total

amine are in this bottle?

grams of riboflavin are in this bottle?

35. Aspirin A bottle of low-strength aspirin contains 120

36. Aspirin A bottle of maximum-

tablets. Each tablet contains 81 mg of aspirin. How

strength aspirin contains 90 tablets.

many total grams of aspirin are in this bottle?

Each tablet contains 500 mg of aspirin. How many total grams of aspirin are in this bottle?

37. Vitamin C A certain brand of vitamin C

grams of vitamin C are in this bottle?

90 Tablets 500 mg

38. Vitamin C A certain brand of vitamin C contains 600 mg

contains 500 mg per tablet. A bottle contains 240 tablets. How many total

Aspirin

per tablet. A bottle contains 150 vitamins. How many 240

total grams of vitamin C are in this bottle?

Coca-Cola Bottles The soft drink Coke is sold throughout the world. Although the size of the bottle varies between different countries, a “six-pack” is sold everywhere. For each of the problems below, find the number of liters in a “6-pack” from the given bottle size.

Bottle size

39.

Estonia

500 mL

40.

Israel

350 mL

41.

Jordan

250 mL

42.

Kenya

300 mL

Liters in a 6-pack

Paul A. Souders/Corbis

Country

6.3 Problem Set 43. Nursing A patient is prescribed a dosage of Ceclor® of 561 mg. How many grams is the dosage?

45. Nursing Dilatrate®-SR comes in 40 milligram capsules.

431

44. Nursing A patient is prescribed a dosage of 425 mg. How many grams is the dosage?

46. Nursing A brand of methyldopa comes in 250 milligram

Use this information to determine how many capsules

tablets. Use this information to determine how many

should be given for the prescribed dosages.

capsules should be given for the prescribed dosages.

a. 120 mg

a. 0.125 gram

b. 40 mg

b. 750 milligrams

c. 80 mg

c. 0.5 gram

Getting Ready for the Next Section Perform the indicated operations.

47. 8  2.54

48. 9  3.28

49. 3  1.06  2

50. 3  5  3.79

51. 80.5  1.61

52. 96.6  1.61

53. 125  2.50

54. 165  2.20

55. 2,000  16.39

56. 2,200  16.39

(Round your answer to the nearest whole number.)

9 5

57.  (120)  32

9 5

58.  (40)  32

(Round your answer to the nearest whole number.)

5(102  30) 9

59. 

5(105  42) 9

60. 

432

Chapter 6 Measurement

Maintaining Your Skills Write each decimal as an equivalent proper fraction or mixed number.

61. 0.18

62. 0.04

63. 0.09

64. 0.045

65. 0.8

66. 0.08

67. 1.75

68. 3.125

Write each fraction or mixed number as a decimal. 3 4

70. 

3 5

74. 

69. 

73. 

9 10

71. 

17 20

7 8

75. 3 

1 8

72. 

1 16

5 8

76. 1 

Use the definition of exponents to simplify each expression.

77.

1

 2 

3

81. (0.5)3

78.

5

 9 

2

82. (0.05)3

1

 2

79. 2 

83. (2.5)2

2

80.

1

 3 

4

84. (0.5)4

Converting Between the Two Systems and Temperature A Converting Between the U.S. and Metric Systems Because most of us have always used the U.S. system of measurement in our everyday lives, we are much more familiar with it on an intuitive level than we

6.4 A B

Convert between the two systems. Convert temperatures between the Fahrenheit and Celsius scales.

are with the metric system. We have an intuitive idea of how long feet and inches are, how much a pound weighs, and what a square yard of material looks like. The metric system is actually much easier to use than the U.S. system. The reason some of us have such a hard time with the metric system is that we don’t

Examples now playing at

have the feel for it that we do for the U.S. system. We have trouble visualizing

MathTV.com/books

how long a meter is or how much a gram weighs. The following list is intended to give you something to associate with each basic unit of measurement in the metric system:

1. A meter is just a little longer than a yard. 2. The length of the edge of a sugar cube is about 1 centimeter. 3. A liter is just a little larger than a quart. 4. A sugar cube has a volume of approximately 1 milliliter. 5. A paper clip weighs about 1 gram. 6. A 2-pound can of coffee weighs about 1 kilogram.

TABLE 1

ACTUAL CONVERSION FACTORS BETWEEN THE METRIC AND U.S. SYSTEMS OF MEASUREMENT The Relationship Between

Is

To Convert From One To The Other, Multiply By

Length inches and centimeters feet and meters

2.54 cm  1 in. 1 m  3.28 ft

1 in. 2.54 cm  or  1 in. 2.54 cm 1m 3.28 ft  or  1m 3.28 ft

1.61 km  1 mi

1.61 km 1 mi  or  1 mi 1.61 km

square inches and square centimeters

6.45 cm2  1 in2

6.45 cm2  1 in2

square meters and square yards

1.196 yd2  1 m2

1 m2 1.196 yd2  or 2 1.196 yd 1 m2

miles and kilometers Area

acres and hectares

1 ha  2.47 acres

1 in2 or 2 6.45 cm

1 ha 2.47 acres  or  2.47 acres 1 ha

Volume cubic inches and milliliters liters and quarts gallons and liters

16.39 mL  1 in3 1.06 qt  1 liter 3.79 liters  1 gal

16.39 mL 1 in3  or  16.39 mL 1 in3 1 liter 1.06 qt  or  1.06 qt 1 liter 1 gal 3.79 liters  or  1 gal 3.79 liters

Weight ounces and grams kilograms and pounds

28.3 g  1 oz 2.20 lb  1 kg

1 oz 28.3 g  or  1 oz 28.3 g 1 kg 2.20 lb  or  1 kg 2.20 lb

6.4 Converting Between the Two Systems and Temperature

433

434

Chapter 6 Measurement There are many other conversion factors that we could have included in Table 1. We have listed only the most common ones. Almost all of them are approximations. That is, most of the conversion factors are decimals that have been rounded to the nearest hundredth. If we want more accuracy, we obtain a table that has more digits in the conversion factors.

PRACTICE PROBLEMS 1. Convert 10 inches to

EXAMPLE 1

centimeters.

SOLUTION

Convert 8 inches to centimeters.

Choosing the appropriate conversion factor from Table 1, we have 2.54 cm 8 in.  8  in.   1 in .  8  2.54 cm  20.32 cm

EXAMPLE 2 2. Convert 16.4 feet to meters.

SOLUTION

Convert 80.5 kilometers to miles.

Using the conversion factor that takes us from kilometers to miles,

we have 1 mi    80.5 km  80.5 km m 1.61 k  80.5  mi 1.61  50 mi So 50 miles is equivalent to 80.5 kilometers. If we travel at 50 miles per hour in a car, we are moving at the rate of 80.5 kilometers per hour.

EXAMPLE 3 3. Convert 10 liters to gallons. Round to the nearest hundredth.

SOLUTION

Convert 3 liters to pints.

Because Table 1 doesn’t list a conversion factor that will take us di-

rectly from liters to pints, we first convert liters to quarts, and then convert quarts to pints. 1.06  qt 2 pt       3 liters  3 liters 1 liter 1 qt  3  1.06  2 pt  6.36 pt

EXAMPLE 4 4. The engine in a car has a 2.2liter displacement. What is the displacement in cubic inches (to the nearest cubic inch)?

The engine in a car has a 2-liter displacement. What is the

displacement in cubic inches?

SOLUTION

We convert liters to milliliters and then milliliters to cubic inches: 1,000  mL 1 in3 2 liters  2 liters      1 liter 16.39  mL 2  1,000   in3 This calculation should be done on a calculator 16.39  122 in3

Answers 1. 25.4 cm 2. 5 m 3. 2.64 gal 4. 134 in3

To the nearest cubic inch

435

6.4 Converting Between the Two Systems and Temperature

EXAMPLE 5

If a person weighs 125 pounds, what is her weight in kilo-

5. A person who weighs 165 pounds weighs how many kilograms?

grams?

SOLUTION

Converting from pounds to kilograms, we have 1 kg 125 lb  125  lb   2.20 lb 

 56.8 kg

1

125  kg 2.20

20 125 130 13 51

POUNDS

To the nearest tenth

B Temperature We end this section with a discussion of temperature in both systems of measurement. In the U.S. system we measure temperature on the Fahrenheit scale. On this scale, water boils at 212 degrees and freezes at 32 degrees. When we write 32 degrees measured on the Fahrenheit scale, we use the notation 32°F (read, “32 degrees Fahrenheit”) In the metric system the scale we use to measure temperature is the Celsius scale (formerly called the centigrade scale). On this scale, water boils at 100 degrees and freezes at 0 degrees. When we write 100 degrees measured on the Celsius scale, we use the notation 100°C (read, “100 degrees Celsius”) °F

°C

32°

°F 212° 0° Ice water

°C 100°

Boiling water

Table 2 is intended to give you a feel for the relationship between the two temperature scales. Table 3 gives the formulas, in both symbols and words, that are used to convert between the two scales. TABLE 2

Situation Water freezes Room temperature Normal body temperature Water boils Bake cookies Broil meat

Temperature Fahrenheit 32°F 68°F 98.6°F 212°F 350°F 554°F

Temperature Celsius 0°C 20°C 37°C 100°C 176.7°C 290°C

Answer 5. 75 kg

436

Chapter 6 Measurement

TABLE 3

To Convert From

Formula In Symbols

Fahrenheit to Celsius

5(F  32) C   9

Celsius to Fahrenheit

9 F  C  32 5

Formula In Words Subtract 32, multiply by 5, and then divide by 9. 9 Multiply by , and then 5 add 32.

The following examples show how we use the formulas given in Table 3. 6. Convert 40°C to degrees Fahrenheit.

EXAMPLE 6 SOLUTION

Convert 120°C to degrees Fahrenheit.

We use the formula 9 F  C  32 5

and replace C with 120: C  120

When

9 F  C  32 5

the formula

9 F  (120)  32 5

becomes

F  216  32 F  248 We see that 120°C is equivalent to 248°F; they both mean the same temperature. 7. A child is running a temperature of 101.6°F. What is her temperature, to the nearest tenth of a degree, on the Celsius scale?

EXAMPLE 7

A man with the flu has a temperature of 102°F. What is his

temperature on the Celsius scale?

SOLUTION

When the formula becomes

F  102 5(F  32) C   9 5(102  32) C   9 5(70) C   9 C  38.9

Rounded to the nearest tenth

The man’s temperature, rounded to the nearest tenth, is 38.9°C on the Celsius scale.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Write the equality that gives the relationship between centimeters and inches. 2. Write the equality that gives the relationship between grams and ounces. 3. Fill in the numerators below so that each conversion factor is equal to 1.

ft

a. 1 meter

qt

b. 1 liter

lb 1 kg

c. 

4. Is it a hot day if the temperature outside is 37°C? Answers 6. 104°F 7. 38.7°C

6.4 Problem Set

437

Problem Set 6.4 A

B Use Tables 1 and 3 to make the following conversions. [Examples 1–7]

1. 6 in. to centimeters

2. 1 ft to centimeters

3. 4 m to feet

4. 2 km to feet

5. 6 m to yards

6. 15 mi to kilometers

7. 20 mi to meters (round to the nearest hundred meters)

8. 600 m to yards

9. 5 m 2 to square yards (round to the nearest hundredth)

10. 2 in2 to square centimeters (round to the nearest tenth)

11. 10 ha to acres

12. 50 a to acres

13. 500 in3 to milliliters

14. 400 in3 to liters

15. 2 L to quarts

16. 15 L to quarts

17. 20 gal to liters

18. 15 gal to liters

19. 12 oz to grams

20. 1 lb to grams (round to the nearest 10 grams)

21. 15 kg to pounds

22. 10 kg to ounces

23. 185°C to degrees Fahrenheit

24. 20°C to degrees Fahrenheit

25. 86°F to degrees Celsius

26. 122°F to degrees Celsius

438

Chapter 6 Measurement

Applying the Concepts 27. Temperature The chart shows the temperatures for

28. Google Earth The Google Earth image is of Lake Clark

some of the world’s hottest places. Convert the temper-

National Park in Alaska. Lake Clark has an average

ature in Al’Aziziyah to Celsius.

temperature of 40 degrees Fahrenheit. What is its average temperature in Celsius to the nearest degree?

160

Heating Up 136.4˚F Al’Aziziyah, Libya

140 120

134.0˚F Greenland Ranch, Death Valley, United States 131.0˚F Ghudamis, Libya 131.0˚F Kebili, Tunisia

100 80

130.1˚F Tombouctou, Mali 60

Source: Aneki.com

40

Nursing Liquid medication is usually given in milligrams per milliliter. Use the information to find the amount a patient should take for a prescribed dosage.

29. Vantin© has a dosage strength of 100 mg/5 mL. If a

30. A brand of amoxicillin has a dosage strength of

patient is prescribed a dosage of 150 mg, how many

125 mg/5 mL. If a patient is prescribed a dosage of 25

milliliters should she take?

mg, how many milliliters should she take?

Calculator Problems Set up the following problems as we have set up the examples in this section. Then use a calculator for the calculations and round your answers to the nearest hundredth.

31. 10 cm to inches

32. 100 mi to kilometers

33. 25 ft to meters

34. 400 mL to cubic inches

35. 49 qt to liters

36. 65 L to gallons

37. 500 g to ounces

38. 100 lb to kilograms

6.4 Problem Set

439

39. Weight Give your weight in kilograms.

40. Height Give your height in meters and centimeters.

41. Sports The 100-yard dash is a popular race in track.

42. Engine Displacement A 351-cubic-inch engine has a dis-

How far is 100 yards in meters?

placement of how many liters?

43. Sewing 25 square yards of material is how many square

44. Weight How many grams does a 5 lb 4 oz roast weigh?

meters?

45. Speed 55 miles per hour is equivalent to how many

46. Capacity A 1-quart container holds how many liters?

kilometers per hour?

47. Sports A high jumper jumps 6 ft 8 in. How many meters

48. Farming A farmer owns 57 acres of land. How many

is this?

hectares is that?

49. Body Temperature A person has a temperature of 101°F.

50. Air Temperature If the temperature outside is 30°C, is it a

What is the person’s temperature, to the nearest tenth,

better day for water skiing or for snow skiing?

on the Celsius scale?

Getting Ready for the Next Section Perform the indicated operations.

51. 15  60

52. 25  60

53.

54.

37

27

 45

 46

55. 3  0.25

56. 2  0.75

57. 82  60

58. 73  60

59.

60.

61. 12  4

62. 8  4

75  34

63. 3  60  15

85  42

64. 2  65  45

67. If fish costs $6.00 per pound, find the cost of 15 pounds.

1 65

65. 3  17  

1 60

66. 2  45  

68. If fish costs $5.00 per pound, find the cost of 14 pounds.

440

Chapter 6 Measurement

Maintaining Your Skills Find the mean and the range for each set of numbers.

69. 5, 7, 9, 11

70. 6, 8, 10, 12

71. 1, 4, 5, 10, 10

72. 2, 4, 4, 6, 9

75. 32, 38, 42, 48

76. 53, 61, 67, 75

Find the median and the range for each set of numbers.

73. 15, 18, 21, 24, 29

74. 20, 30, 35, 45, 50

Find the mode and the range for each set of numbers.

77. 20, 15, 14, 13, 14, 18

78. 17, 31, 31, 26, 31, 29

79. A student has quiz scores of 65, 72, 70, 88, 70, and 73.

80. A person has bowling scores of 207, 224, 195, 207, 185,

Find each of the following:

and 182. Find each of the following:

a. mean score

a. mean score

b. median score

b. median score

c. mode of the scores

c. mode of the scores

d. range of scores

d. range of scores

Extending the Concepts Nursing For children, the amount of medicine prescribed is often determined by the child’s weight. Usually, it is calculated from the milligrams per kilogram per day listed on the medication’s box.

81. Ceclor® has a dosage strength of 250 mg/mL. How much should a 42 lb child be given a day if the dosage is 20 mg/kg/day? How many milliliters is that?

Operations with Time and Mixed Units Many occupations require the use of a time card. A time card records the number of hours and minutes at work. At the end of a work week the hours and minutes are totaled separately, and then the minutes are converted to hours.

6.5 A

Convert mixed units to a single unit.

B C

Add and subtract mixed units. Use multiplication with mixed units.

In this section we will perform operations with mixed units of measure. Mixed units are used when we use 2 hours 30 minutes, rather than 2 and a half hours, or 5 feet 9 inches, rather than five and three-quarter feet. As you will see, many of these types of problems arise in everyday life.

Examples now playing at

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A Converting Time to Single Units is

To Convert from One to the Other, Multiply by

1 min  60 sec

60 sec 1 min  or  60 sec 1 min

The Relationship Between minutes and seconds

1 hr  60 min

hours and minutes

EXAMPLE 1

PRACTICE PROBLEMS Convert 3 hours 15 minutes to

a. Minutes SOLUTION

60 min 1 hr  or  60 min 1 hr

b. Hours

1. Convert 2 hours 45 minutes to a. Minutes b. Hours

a. To convert to minutes, we multiply the hours by the conversion factor and then add minutes: 60 min 3 hr 15 min  3 hr    15 min 1 hr  180 min  15 min  195 min

b. To convert to hours, we multiply the minutes by the conversion factor and then add hours: 1 hr 3 hr 15 min  3 hr  15 min   60 min  3 hr  0.25 hr  3.25 hr

B Addition and Subtraction with Mixed Units EXAMPLE 2 SOLUTION

Add 5 minutes 37 seconds and 7 minutes 45 seconds.

46 sec.

First, we align the units properly 5 min

2. Add 4 min. 27 sec. and 8 min.

37 sec

 7 min 45 sec  12 min 82 sec Since there are 60 seconds in every minute, we write 82 seconds as 1 minute 22 seconds. We have 12 min 82 sec  12 min  1 min 22 sec  13 min 22 sec

6.5 Operations with Time and Mixed Units

Answers 1. a 165 minutes b. 2.75 hours 2. 13 min 13 sec

441

442

Chapter 6 Measurement The idea of adding the units separately is similar to adding mixed fractions. That is, we align the whole numbers with the whole numbers and the fractions with the fractions. Similarly, when we subtract units of time, we “borrow” 60 seconds from the minutes column, or 60 minutes from the hours column.

3. Subtract 42 min from 6 hr 25 min.

EXAMPLE 3 SOLUTION

Subtract 34 minutes from 8 hours 15 minutes.

Again, we first line up the numbers in the hours column, and then the numbers in the minutes column: 8 hr

15 min

 34 min 

7 hr

75 min

 34 min  7 hr 41 min

C Multiplication with Mixed Units Next we see how to multiply and divide using units of measure.

4. Rob is purchasing 4 halibut. The fish cost $5.00 per pound, and each weighs 3 lb 8 oz. What is the cost of the fish?

EXAMPLE 4

Jake purchases 4 halibut. The fish cost $6.00 per pound,

and each weighs 3 lb 12 oz. What is the cost of the fish?

SOLUTION

First, we multiply each unit by 4: 3 lb

12 oz

 4  12 lb 48 oz To convert the 48 ounces to pounds, we multiply the ounces by the conversion factor. 1 lb 12 lb 48 oz  12 lb  48 oz   16 oz  12 lb  3 lb  15 lb Finally, we multiply the 15 lb and $6.00/lb for a total price of $90.00

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Explain the difference between saying 2 and a half hours and saying 2 hours and 50 minutes. 2. How are operations with mixed units of measure similar to operations with mixed numbers? 3. Why do we borrow a 60 from the minutes column for the seconds column when subtracting in Example 3? 4. Give an example of when you may have to use multiplication with mixed units of measure.

Answers 3. 5 hr 43 min 4. $70

6.5 Problem Set

443

Problem Set 6.5 A Use the tables of conversion factors given in this section and other sections in this chapter to make the following conversions. (Round your answers to the nearest hundredth.) [Example 1]

1. 4 hours 30 minutes to a. Minutes b. Hours

4. 4 hours 40 minutes to a. Minutes b. Hours

7. 5 minutes 20 seconds to a. Seconds b. Minutes

10. 3 pounds 4 ounces to a. Ounces b. Pounds

13. 4 feet 6 inches to a. Inches b. Feet

16. 3 feet 4 inches to a. Inches b. Feet

2. 2 hours 45 minutes to a. Minutes b. Hours

5. 6 minutes 30 seconds to a. Seconds b. Minutes

8. 4 minutes 40 seconds to a. Seconds b. Minutes

11. 4 pounds 12 ounces to a. Ounces b. Pounds

14. 3 feet 3 inches to a. Inches b. Feet

17. 2 gallons 1 quart a. Quarts b. Gallons

3. 5 hours 20 minutes to a. Minutes b. Hours

6. 8 minutes 45 seconds to a. Seconds b. Minutes

9. 2 pounds 8 ounces to a. Ounces b. Pounds

12. 5 pounds 16 ounces to a. Ounces b. Pounds

15. 5 feet 9 inches to a. Inches b. Feet

18. 3 gallons 2 quarts a. Quarts b. Gallons

444

Chapter 6 Measurement

B Perform the indicated operation. Again, remember to use the appropriate conversion factor. [Examples 2, 3] 19. Add 4 hours 47 minutes and 6 hours 13 minutes.

20. Add 5 hours 39 minutes and 2 hours 21 minutes.

21. Add 8 feet 10 inches and 13 feet 6 inches

22. Add 16 feet 7 inches and 7 feet 9 inches.

23. Add 4 pounds 12 ounces and 6 pounds 4 ounces.

24. Add 11 pounds 9 ounces and 3 pounds 7 ounces.

25. Subtract 2 hours 35 minutes from 8 hours 15 minutes.

26. Subtract 3 hours 47 minutes from 5 hours 33 minutes.

27. Subtract 3 hours 43 minutes from 7 hours 30 minutes.

28. Subtract 1 hour 44 minutes from 6 hours 22 minutes.

29. Subtract 4 hours 17 minutes from 5 hours 9 minutes.

30. Subtract 2 hours 54 minutes from 3 hours 7 minutes.

Applying the Concepts 31. Fifth Avenue Mile The chart shows the times of the five

32. Cars The chart shows the fastest cars in America. Con-

fastest runners for 2005’s Continental Airlines Fifth

vert the speed of the Ford GT to feet per second. Round

Avenue Mile. How much faster was Craig Mottram than

to the nearest tenth.

Rui Silva?

Ready for the Races

Fastest on Fifth

Ford GT 205 mph

Craig Mottram, AUS

3:49.90

Alan Webb, USA

3:51.40

Evans 487 210 mph

Elkanah Angwenyi, KEN

3:54.30

Saleen S7 Twin Turbo 260 mph

Anthony Famiglietti, USA

3:57.10

SSC Ultimate Aero 273 mph

Rui Silva, POR

3:57.40

Source: www.coolrunning.com, 2005

Source: Forbes.com

6.5 Problem Set

445

Triathlon The Ironman Triathlon World Championship, held each October in Kona on the island of Hawaii, consists of three parts: a 2.4-mile ocean swim, a 112-mile bike race, and a 26.2-mile marathon. The table shows the results

Triathlete

Swim Time (Hr:Min:Sec)

Bike Time Run Time (Hr:Min:Sec) (Hr:Min:Sec)

Peter Reid

0:50:36

4:40:04

2:47:38

Lori Bowden

0:56:51

5:09:00

3:02:10

Total Time (Hr:Min:Sec)

Sanford/Agliolo/Corbis

from the 2003 event.

33. Fill in the total time column.

34. How much faster was Peter’s total time than Lori’s?

35. How much faster was Peter than Lori in the swim?

36. How much faster was Peter than Lori in the run?

37. Cost of Fish Fredrick is purchasing four whole salmon.

38. Cost of Steak Mike is purchasing eight top sirloin

The fish cost $4.00 per pound, and each weighs 6 lb 8

steaks. The meat costs $4.00 per pound, and each

oz. What is the cost of the fish?

steak weighs 1 lb 4 oz. What is the total cost of the steaks?

39. Stationary Bike Maggie rides a stationary bike for 1 hour

40. Gardening Scott works in his garden for 1 hour and 5

and 15 minutes, 4 days a week. After 2 weeks, how

minutes, 3 days a week. After 4 weeks, how many

many hours has she spent riding the stationary bike?

hours has Scott spent gardening?

41. Cost of Fabric Allison is making a quilt. She buys 3 yards

42. Cost of Lumber Trish is building a fence. She buys six

and 1 foot each of six different fabrics. The fabrics cost

fence posts at the lumberyard, each measuring 5 ft 4 in.

$7.50 a yard. How much will Allison spend?

The lumber costs $3 per foot. How much will Trish spend?

43. Cost of Avocados Jacqueline is buying six avocados.

44. Cost of Apples Mary is purchasing 12 apples. Each apple

Each avocado weighs 8 oz. How much will they cost

weighs 4 oz. If the cost of the apples is $1.50 a pound,

her if avocados cost $2.00 a pound?

how much will Mary pay?

446

Chapter 6 Measurement

Maintaining Your Skills 45. Caffeine Content The following bar chart shows the amount of caffeine in five different soft drinks. Use the information

CAFFEINE CONTENT IN SOFT DRINKS

100

Drink

80 60

Caffeine (In Milligrams)

Jolt Mountain Dew

20

Coca-Cola

0

Diet Pepsi

7 Up

Diet Pepsi

Mountain Dew

Coca-Cola

40

Jolt

Caffeine (in milligrams)

in the bar chart to fill in the table.

7 Up

46. Exercise The following bar chart shows the number of calories burned in 1 hour of exercise by a person who weighs

CALORIES BURNED BY A 150-POUND PERSON IN ONE HOUR

700 600 500

Activity

400

Bicycling

300

Bowling

200

Handball

100 Skiing

Jogging

Jazzercize

Handball

Jazzercise

Bowling

0

Bicycling

Number of calories burned in one hour

150 pounds. Use the information in the bar chart to fill in the table.

Jogging Skiing

Activity

Extending the Concepts 47. In 2003, the horse Funny Cide won the Kentucky Derby with a time of 2:01.19, or two minutes and 1.19 seconds. The record time for the Kentucky Derby is still held by Secretariat, who won the race with a time of 1:59.40 in 1973. How much faster did Secretariat run than Funny Cide 30 years later?

48. In 2003, the horse Empire Maker won the Belmont Stakes with a time of 2:28.20, or two minutes and 28.2 seconds. The record time for the Belmont Stakes is still held by Secretariat, who won the race with a time of 2:24.00 in 1973. How much faster did Secretariat run in 1973 than Empire Maker 30 years later?

Calories

Chapter 6 Summary Conversion Factors [6.1, 6.2, 6.3, 6.4, 6.5] EXAMPLES To convert from one kind of unit to another, we choose an appropriate conversion factor from one of the tables given in this chapter. For example, if we want to convert 5 feet to inches, we look for conversion factors that give the relationship between feet and inches. There are two conversion factors for feet and

1. Convert 5 feet to inches. 12 in. 5 ft  5  ft   1 ft  5  12 in.  60 in.

inches: 12 in.  1 ft

and

1 ft  12 in.

Length [6.1] 2. Convert 8 feet to yards.

U.S. SYSTEM The Relationship Between

Is

To Convert From One To The Other, Multiply By

feet and inches

12 in.  1 ft

12 in.  1 ft

or

1 ft  12 in.

feet and yards

1 yd  3 ft

3 ft  1 yd

or

1 yd  3 ft

feet and miles

1 mi  5,280 ft

5,280 ft  1 mi

or

1 mi  5,280 ft

Is

To Convert From One To The Other, Multiply By

millimeters (mm) and meters (m)

1,000 mm  1 m

1,000 mm  1m

or

1m  1,000 mm

centimeters (cm) and meters

100 cm  1 m

100 cm  1m

or

1m  100 cm

decimeters (dm) and meters

10 dm  1 m

10 dm  1m

or

1m  10 dm

dekameters (dam) and meters

1 dam  10 m

10 m  1 dam

or

1 dam  10 m

100 m  1 hm

or

1 hm  100 m

1,000 m  1 km

or

1 km  1,000 m

hectometers (hm) and meters

1 hm  100 m

kilometers (km) and meters

1 km  1,000 m

2

 23 yd

3. Convert 25 millimeters to

METRIC SYSTEM The Relationship Between

1 yd    8 ft  8 ft 3 ft 8   yd 3

Chapter 6

Summary

meters. 1m 25 mm  25  mm   1,000  mm 25 m   1,000  0.025 m

447

448

Chapter 6 Measurement

Area [6.2] 4. Convert 256 acres to square miles. 1 mi2    256 acres  256 acres 640 ac  res 256   mi2 640  0.4 mi2

U.S. SYSTEM The Relationship Between square inches and square feet square yards and square feet acres and square feet acres and square miles

Is 144 in2  1 ft2 9 ft2  1 yd2 1 acre  43,560 ft2 640 acres  1 mi2

To Convert From One To The Other, Multiply By 144 in2  1 ft2

or

1 ft2  144 in2

9 ft2  1 yd2

or

1 yd2  9 ft2

43,560 ft2  1 acre

or

1 acre  43,560 ft2

640 acres  1 mi2

or

1 mi2  640 acres

METRIC SYSTEM The Relationship Between

Is

To Convert From One To The Other, Multiply By

square millimeters and square centimeters

1 cm2  100 mm2

100 mm2  1 cm2

or

1 cm2  100 mm2

square centimeters and square decimeters

1 dm2  100 cm2

100 cm2  1 dm2

or

1 dm2  100 cm2

1 m2  100 dm2

100 dm2  1 m2

or

1 m2  100 dm2

100 m2  1a

or

1a  100 m2

100 a  1 ha

or

1 ha  100 a

square decimeters and square meters square meters and ares (a) ares and hectares (ha)

1 a  100 m2

1 ha  100 a

Volume [6.2] U.S. SYSTEM The Relationship Between cubic inches (in3) and cubic feet (ft3) cubic feet and cubic yards (yd3)

Is 1 ft3  1,728 in3

1 yd3  27 ft3

To Convert From One To The Other, Multiply By 1,728 in3  1 ft3 27 ft3  1 yd3

or

1 ft3  1,728 in3

1 yd3 or 3 27 ft

1 pt 16 f l oz  or   1 pt 16 fl oz

fluid ounces (fl oz) and pints (pt)

1 pt  16 fl oz

pints and quarts (qt)

1 qt  2 pt

2 pt 1 qt  or  1 qt 2 pt

1 gal  4 qt

4 qt 1 gal  or  1 gal 4 qt

quarts and gallons (gal)

Chapter 6

METRIC SYSTEM The Relationship Between

5. Convert 2.2 liters to milliliters. To Convert From One To The Other, Multiply By

Is

1 liter  1,000 mL

milliliters (mL) and liters

1 liter (L)  1,000 mL

1,000 mL  1 liter

hectoliters (hL) and liters

100 liters  1 hL

1 hL 100 liters  or  100 liters 1 hL

kiloliters (kL) and liters

1,000 liters (L)  1 kL

449

Summary

or

1,000 mL    2.2 liters  2.2 liters 1 liter  2.2  1,000 mL  2,200 mL

1 kL  1,000 liters

1,000 liters  or 1 kL

Weight [6.3] 6. Convert 12 pounds to ounces. 16 oz    12 lb  12 lb 1 lb

U.S. SYSTEM The Relationship Between

To Convert From One To The Other, Multiply By

Is

ounces (oz) and pounds (lb)

1 lb  16 oz

pounds and tons (T)

1 T  2,000 lb

16 oz  1 lb

or

1 lb  16 oz

2,000 lb  1T

or

1T  2,000 lb

 12  16 oz  192 oz

7. Convert 3 kilograms to METRIC SYSTEM The Relationship Between

Is

milligrams (mg) and grams (g)

1 g  1,000 mg

centigrams (cg) and grams

1 g  100 cg

kilograms (kg) and grams metric tons (t) and kilograms

1,000 g  1 kg 1,000 kg  1 t

To Convert From One To The Other, Multiply By 1g 1,000 mg  or  1g 1,000 mg 100 cg  1g

1g or  100 cg

1,000 g  1 kg

1 kg or  1,000 g

1t 1,000 kg  or  1,000 kg 1t

centigrams. 1,000 g  100 cg      3 kg  3 kg 1k g 1g    3  1,000  100 cg  300,000 cg

450

Chapter 6 Measurement

Converting Between the Systems [6.4] 8. Convert 8 inches to centimeters.

CONVERSION FACTORS

2.54 cm    8 in.  8 in. 1 in .  8  2.54 cm  20.32 cm

The Relationship Between

To Convert From One To The Other, Multiply By

Is

Length inches and centimeters feet and meters miles and kilometers

2.54 cm  1 in. 1 m  3.28 ft 1.61 km  1 mi

1 in. 2.54 cm  or  1 in. 2.54 cm 3.28 ft 1m  or  1m 3.28 ft 1.61 km 1 mi  or  1.61 km 1 mi

Area square inches and square centimeters

6.45 cm2  1 in2

6.45 cm2  1 in2

1 in2 or 2 6.45 cm

square meters and square yards

1.196 yd2  1 m2

1.196 yd2  1 m2

1 m2 or 2 1.196 yd

acres and hectares

1 ha  2.47 acres

1 ha 2.47 acres  or  2.47 acres 1 ha

Volume cubic inches and milliliters liters and quarts gallons and liters

16.39 mL  1 in3 1.06 qt  1 liter 3.79 liters  1 gal

16.39 mL  1 in3 1.06 qt  1 liter

1 in3 or  16.39 mL 1 liter or  1.06 qt

1 gal 3.79 liters  or  1 g al 3.79 liters

Weight ounces and grams kilograms and pounds

28.3 g  1 oz 2.20 lb  1 kg

1 oz 28.3 g  or  1 oz 28.3 g 2.20 lb  1 kg

1 kg or  2.20 lb

Temperature [6.4] 9. Convert 120°C to degrees Fahrenheit.

To Convert From

Formula In Symbols

9 F  C  32 5

Fahrenheit to Celsius

5(F  32) C   9

9 F  (120)  32 5

Celsius to Fahrenheit

9 F  C  32 5

F  216  32 F  248

Formula In Words Subtract 32, multiply by 5, and then divide by 9. 9 Multiply by , and then 5 add 32.

Time [6.5] 10. Convert 3 hours 45 minutes to minutes. 60 min

3 hr   1 hr  45 min  180 min  45 min  225 min

The Relationship Between minutes and seconds

hours and minutes

Is

To Convert From One To The Other, Multiply By

1 min  60 sec

60 sec 1 min  or  60 sec 1 min

1 hr  60 min

1 hr 60 min  or  60 min 1 hr

Chapter 6

Review

Use the tables given in this chapter to make the following conversions. [6.1-6.4]

1. 12 ft to inches

2. 18 ft to yards

3. 49 cm to meters

4. 2 km to decimeters

5. 10 acres to square feet

6. 7,800 m2 to ares

7. 4 ft2 to square inches

8. 7 qt to pints

9. 24 qt to gallons

10. 5 L to milliliters

11. 8 lb to ounces

12. 2 lb 4 oz to ounces

13. 5 kg to grams

14. 5 t to kilograms

15. 4 in. to centimeters

16. 7 mi to kilometers

17. 7 L to quarts

18. 5 gal to liters

19. 5 oz to grams

20. 9 kg to pounds

21. 120°C to degrees Fahrenheit

22. 122°F to degrees Celsius

Chapter 6

Review

451

452

Chapter 6 Measurement

Work the following problems. Round answers to the nearest hundredth where necessary.

23. A case of soft drinks holds 24 cans. If each can holds

24. Change 862 mi to feet. [6.1]

355 ml, how many liters are there in the whole case? [6.2]

25. Glacier Bay National Monument covers 2,805,269

26. How many ounces does a 134-lb person weigh? [6.3]

acres. What is the area in square miles? [6.2]

27. Change 250 mi to kilometers. [6.1]

28. How many grams is 7 lb 8 oz? [6.4]

29. Construction A 12-square-meter patio is to be built using

30. Capacity If a regular drinking glass holds 0.25 liter of

bricks that measure 10 centimeters by 20 centimeters.

liquid, how many glasses can be filled from a 6.5-liter

How many bricks will be needed to cover the patio? [6.2]

container? [6.2]

31. Filling an Aquarium How many 8-fluid-ounce glasses of water will it take to fill a 5-gallon aquarium? [6.2]

32. Comparing Area On April 3, 2000, USA Today changed the size of its paper. Previous to this date, each page of 1

1

the paper was 132 inches wide and 224 inches long, giving each page an area of

3 3008

in . Convert this area 2

to square feet. [6.2]

33. Speed The instrument display below shows a speed of

34. Volcanoes Pyroclastic flows

188 kilometers per hour. What is the speed in miles per

are high speed avalanches of

hour? Round to the nearest whole number. [6.4]

volcanic gases and ash that accompany some volcano eruptions. Pyroclastic flows have been known to travel at more than 80 kilometers per hour.

a. Convert 80 km/hr to miles nearest whole number.

USGS

per hour. Round to the

b. Could you outrun a pyroclastic flow on foot, on a bicycle, or in a car?

35. Speed A race car is traveling at 200 miles per hour. What is the speed in kilometers per hour? [6.4]

36. 4 hours 45 minutes to [6.5] a. Minutes b. Hours

37. Add 4 pounds 4 ounces and 8 pounds 12 ounces. [6.5]

38. Cost of Fish. Mark is purchasing two whole salmon. The fish cost $5.00 per pound, and each weighs 12 lb 8 oz. What is the cost of the fish? [6.5]

Chapter 6

Cumulative Review

Simplify.

1.

2.

7,520

6,000

3. 156  13

4. 9(7  2)

7. 12  81  32

8. 

3,999

599 8,640

5. 643 1 ,3 6 2 

6. 28

9. 25  13

13. 5.4  2.58  3.09

3 1

17. 17  

3 8

3 5

21. (2.4)  (0.25)

39 3

10. (10  4)  (212  100)

11. 

12. 10.5(2.7)

14. 45.7  2.86

15. 2.54 0 .5 

16. 

8 25

2

329 47

7 50



1 4

 4  2 1

19. 16  1  2

22. 249   325 

23. 13    

25. 46  4  y

26.   

3 14

1

2

1 2



18.   

3

20. 15  3

5 42

Solve.

24. 2  x  15

27. Find the perimeter and area of the figure below.

2 3

12 x

28. Find the perimeter of the figure below.

5 6

3 4

cm

cm

6 in. 3 in.

15 in.

1

1 3 cm

15 in.

29. Find the difference between 62 and 15.

1

30. If a car travels 142 miles in 22 hours, what is its rate in miles per hour?

31. What number is 24% of 7,450?

2

33. Find 3 of the product of 7 and 9.

32. Factor 126 into a product of prime factors.

34. If 5,280 feet  1 mile, convert 3,432 feet to miles.

Chapter 6

Cumulative Review

453

Chapter 6

Test

Use the tables in the chapter to make the following conversions.

1. 7 yd to feet

2. 750 m to kilometers

3. 3 acres to square feet

4. 432 in2 to square feet

5. 10 L to milliliters

6. 5 mi to kilometers

7. 10 L to quarts

8. 80°F to degrees Celsius (round to the nearest tenth)

Work the following problems. Round answers to the nearest hundredth.

9. How many gallons are there in a 1-liter bottle of cola?

11. A car engine has a displacement of 409 in3. What is the

10. Change 579 yd to inches.

12. Change 75 qt to liters.

displacement in cubic feet?

13. Change 245 ft to meters.

14. How many liters are contained in an 8-quart container?

15. Construction A 40-square-foot pantry floor is to be tiled

16. Filling an Aquarium How many 12-fluid-ounce glasses of

using tiles that measure 8 inches by 8 inches. How

water will it take to fill a 6-gallon aquarium?

many tiles will be needed to cover the pantry floor?

17. 5 hours 30 minutes to a. Minutes b. Hours

454

Chapter 6 Measurement

18. Add 3 pounds 4 ounces and 7 pounds 12 ounces.

Chapter 6 Projects MEASUREMENT

GROUP PROJECT Body Mass Index Number of People Time Needed Equipment Background

2

height in meters. According to the Centers for Disease Control and Prevention, a healthy BMI

25 minutes

for adults is between 18.5 and 24.9. Children

Pencil, paper, and calculator

aged 2–20 have a healthy BMI if they are in the

Body mass index (BMI) is computed by using a mathematical formula in which one’s weight in kilograms is divided by the square of one’s

Height

4’10”

5th to 84th percentile for their age and sex. A high BMI is predictive of cardiovascular disease.

5’2”

5’9”

6’1”

Weight 100

120

140

200

Procedure

Complete the given BMI chart using the following conversion factors. 1 inch  2.54 cm, 1 meter  100 cm, 1 kg  2.2 lb

Example

5’4”, 120 lbs

1. Convert height to inches. 12 in. 5 feet    60 in. 1 ft 5’4”  64 in. Then, convert height to meters. 2.54 cm 64 in.    162.56 cm 1 in.

2. Convert weight to kilograms. 1 kg 120 lbs   54.5 kg 2.2 lbs weight in kg (height in m)

3. Compute . 2 54.5 2 21 (1.6256)

1m 162.56 cm    1.6256 m 100 cm

Chapter 6

Projects

455

RESEARCH PROJECT Richard Alfred Tapia Richard A. Tapia is a mathematician and professor at Rice University in Houston, Texas, where he is Noah Harding Professor of Computational and Applied Mathematics. His parents immigrated from Mexico, separately, as teenagers to provide better educational opportunities for themselves and future generations. Born in Los tend college. In addition to being internationally known for his research, Tapia has helped his department at Rice become a national leader in awarding Ph.D. degrees to women and minority recipients. Research the life and work of Dr. Tapia. Summarize your results in an essay.

456

Chapter 6 Measurement

Courtesy of Rice University

Angeles, Tapia was the first in his family to at-

Introduction to Algebra

7 Chapter Outline 7.1 Positive and Negative Numbers 7.2 Addition with Negative Numbers 7.3 Subtraction with Negative Numbers 7.4 Multiplication with Negative Numbers 7.5 Division with Negative Numbers 7.6 Simplifying Algebraic Expressions

Introduction The Grand Canyon, located in the state of Arizona, is a large gorge created by the Colorado River over millions of years. Much of the Grand Canyon is located in the Grand Canyon National Park, which receives over four million visitors per year. Visitors come to hike trails and view the magnificent rock formations.

The Grand Canyon Hiking Trails North Rim Trailhead

Yaki Point

Change in altitude

+



Bright Angel Trailhead

Colorado River

Many of the hiking trails have significant changes in altitude. We sometimes represent changes in altitude with negative numbers. In this chapter we will work problems involving both negative numbers and some of the trails found in the Grand Canyon.

457

Chapter Pretest The pretest below contains problems that are representative of the problems you will find in the chapter. Give the opposite of each number.

2. 3

1. 10

Place either  or between the numbers so that the resulting statement is true. 5  6

6 5

3. 

4

4. 2

Simplify each expression.

6. (1)

5.  8 Perform the indicated operations.

7. 9  19

3 5

11. 40  (7)

2 3

4

 5 

3 20

10.       

3

 5

13.    

12. 5(4)

40 5

1 10

2 5

9.    

8. 3.42  (6.89)



14. 21  (7)

0 1

16. 

15. 

Simplify the following expressions as much as possible. 7  4(1) 23

18. 10  2(1  3) 19. 

17. (2)3

20. (3x  4)  9

21. 5(3y  2)

22. 4b  3b

23. On a certain day, the temperature reaches a high of 30° above 0 and a low of 5° below 0. What is the difference between the high and low temperatures for the day?

Getting Ready for Chapter 7 The problems below review material covered previously that you need to know in order to be successful in Chapter 7. If you have any difficulty with the problems here, you need to go back and review before going on to Chapter 7.

1. Use the associative property to rewrite the expression: 5(3  2) 2. Use the distributive property to rewrite the expression: 4  7  4  2 Perform the indicated operation.

3. 60.3  49.8

10. 6  3

4. 9  0

11. 60  20

5. 0.4(0.8)

12. 8  8

17. Find the perimeter of the square.

6. 7  7

7 8

1 10

5 14

13.   

2

3

14. 12 

15. 12  4

18. Find the area of the rectangle.

6 in. 75 ft 6 in. 100 ft

458

Chapter 7 Introduction to Algebra

4 5

8.   

7. 53

9. 14  8

16. 12  3

Positive and Negative Numbers

7.1 Objectives A Use the number line and inequality

Introduction . . . Before the late nineteenth century, time zones did not exist. Each town would set their clocks according to the motions of the Sun. It was not until the late 1800s that a system of worldwide time zones was developed. This system divides the earth into 24 time zones with Greenwich, England designated as the center of the time zones (GMT). This location is assigned a value of zero. Each of the World Time Zones is assigned a number ranging from 12 to 12 depending on its po-

symbols to compare numbers.

B

Find the absolute value of a number.

C D

Find the opposite of a number. Solve applications involving negative numbers.

sition east or west of Greenwich, England.

‒11 ‒10 ‒9 ‒8 ‒7 ‒6 ‒5 ‒4 ‒3 ‒2 ‒1 0 1 2

3 4 5 6 7 8

Examples now playing at

9 10 11 122

MathTV.com/books

If New York is 5 time zones to the left of GMT, this would be noted as 5:00 GMT.

A Comparing Numbers To see the relationship between negative and positive numbers, we can extend the number line as shown in Figure 1. We first draw a straight line and label a convenient point with 0. This is called the origin, and it is usually in the middle of the line. We then label positive numbers to the right (as we have done previously), and negative numbers to the left.

−5

−4

−3

−2

−1

Negative numbers

Note

Positive direction

Negative direction

0

+1

+2

+3

+4

+5

A number, other than 0, with no sign ( or ) in front of it is assumed to be positive. That is, 5  5.

Positive numbers

Origin FIGURE 1

The numbers increase going from left to right. If we move to the right, we are moving in the positive direction. If we move to the left, we are moving in the negative direction. Any number to the left of another number is considered to be smaller than the number to its right.

−4 < −2 −5

−4

−3

−2

−1

0

+1

+2

+3

+4

+5

−4 is less than −2 because −4 is to the left of −2 on the number line FIGURE 2 We see from the line that every negative number is less than every positive number.

7.1 Positive and Negative Numbers

459

460

Chapter 7 Introduction to Algebra In algebra we can use inequality symbols when comparing numbers.

Notation If a and b are any two numbers on the number line, then a  b is read “a is less than b” a b is read “a is greater than b”

As you can see, the inequality symbols always point to the smaller of the two numbers being compared. Here are some examples that illustrate how we use the inequality symbols.

PRACTICE PROBLEMS Write each statement in words. 1. 2  8

EXAMPLE 1

3  5 is read “3 is less than 5.” Note that it would also be

correct to write 5 3. Both statements, “3 is less than 5” and “5 is greater than 3,” have the same meaning. The inequality symbols always point to the smaller number.

2. 5 10 (Is this a true statement?)

EXAMPLE 2

0 100 is a false statement, because 0 is less than 100,

not greater than 100. To write a true inequality statement using the numbers 0 and 100, we would have to write either 0  100 or 100 0. 3. 4  4

EXAMPLE 3

3  5 is a true statement, because 3 is to the left of 5

on the number line, and, therefore, it must be less than 5. Another statement that means the same thing is 5 3. 4. 7  2

EXAMPLE 4

5  2 is a true statement, because 5 is to the left of

2 on the number line, meaning that 5 is less than 2. Both statements 5  2 and 2 5 have the same meaning; they both say that 5 is a smaller number than 2.

B Absolute Value It is sometimes convenient to talk about only the numerical part of a number and disregard the sign ( or ) in front of it. The following definition gives us a way of doing this.

Definition The absolute value of a number is its distance from 0 on the number line. We denote the absolute value of a number with vertical lines. For example, the absolute value of 3 is written 3 . Give the absolute value of each of the following. 5. 6 6. 5

The absolute value of a number is never negative because it is a distance, and a distance is always measured in positive units (unless it happens to be 0). Here are some examples of absolute value problems.

Answers 1. 2 is less than 8. 2. 5 is greater than 10. (No.) 3. 4 is less than 4. 4. 7 is less than 2. 5. 6 6. 5

EXAMPLE 5 EXAMPLE 6

5  5

3  3

The number 5 is 5 units from 0.

The number 3 is 3 units from 0.

461

7.1 Positive and Negative Numbers

EXAMPLE 7

7  7

The number 7 is 7 units from 0.

Give the absolute value. 7. 8

C Opposites Definition Two numbers that are the same distance from 0 but in opposite directions from 0 are called opposites.* The notation for the opposite of a is a.

EXAMPLE 8

Give the opposite of each of the following numbers:

8. Give the opposite of each of the following numbers: 8, 10, 0, 4.

5, 7, 1, 5, 8

SOLUTION

The opposite of 5 is 5. The opposite of 7 is 7. The opposite of 1 is 1. The opposite of 5 is (5), or 5. The opposite of 8 is (8), or 8.

We see from this example that the opposite of every positive number is a negative number, and likewise, the opposite of every negative number is a positive number. The last two parts of Example 8 illustrate the following property:

Property If a represents any positive number, then it is always true that (a)  a

In other words, this property states that the opposite of a negative number is a positive number. It should be evident now that the symbols  and  can be used to indicate several different ideas in mathematics. In the past we have used them to indicate addition and subtraction. They can also be used to indicate the direction a number is from 0 on the number line. For instance, the number 3 (read “positive 3”) is the number that is 3 units from zero in the positive direction. On the other hand, the number 3 (read “negative 3”) is the number that is 3 units from 0 in the negative direction. The symbol  can also be used to indicate the opposite of a number, as in (2)  2. The interpretation of the symbols  and  depends on the situation in which they are used. For example: 35

The  sign indicates addition.

72

The  sign indicates subtraction.

7 (5)

The  sign is read “negative” 7. The first  sign is read “the opposite of.” The second  sign is read “negative” 5.

This may seem confusing at first, but as you work through the problems in this chapter you will get used to the different interpretations of the symbols  and . We should mention here that the set of whole numbers along with their opposites forms the set of integers. That is: Integers  {. . . , 3, 2, 1, 0, 1, 2, 3, . . .} *In some books opposites are called additive inverses.

Answers 7. 8 8. 8, 10, 0, 4

462

Chapter 7 Introduction to Algebra

DESCRIPTIVE STATISTICS D

Displaying Negative Numbers

In the table below, the temperatures below zero are represented by negative numbers.

EXAMPLE 9

9. Use the information in the table

low to draw a scatter diagram and a line graph representing the information

below to make both a scatter diagram and a line graph.

in Table 1.

AVERAGE MONTHLY PRECIPITATION SAN LUIS OBISPO, CALIFORNIA

TABLE 1

RECORD LOW TEMPERATURES FOR JACKSON HOLE, WYOMING

Precipitation (mm)

20°

50 F 44 F 32 F 5 F 12 F 19 F 24 F 18 F 14 F 2 F 27 F 49 F

140 120

10° 0 -10° -20° -30° -40°

Dec

Oct

Nov

Sept

July

Aug

May

June

Apr

-50° Jan

January February March April May June July August September October November December

134.1 113.8 11.9 0.8 11.2 55.1

160

100 80

SOLUTION Notice that the vertical axis in the template looks like the number

60

line we have been using. To produce the scatter diagram, we place a dot

40

above each month, across from the temperature for that month. For example,

20

the dot above July will be across from 24°. Doing the same for each of the

30°

20°

20°

Temperature (Fahrenheit)

30°

10° 0 -10° -20° -30° -40°

10° 0 -10° -20° -30° -40°

FIGURE 3 A scatter diagram of Table 1

Dec

Oct

Nov

Aug

Sept

July

June

May

Apr

Feb

Mar

Jan

Dec

Oct

Nov

Sept

July

Aug

June

Apr

-50° May

-50° Mar

In the United States, temperature is measured on the Fahrenheit temperature scale. On this scale, water boils at 212 degrees and freezes at 32 degrees. To denote a temperature of 32 degrees on the Fahrenheit scale, we write 32°F, which is read “32 degrees Fahrenheit.”

graph in Figure 4, we simply connect the dots in Figure 3 with line segments.

Jan

Note

months, we have the scatter diagram shown in Figure 3. To produce the line

Feb

Month

Nov

Sep

July

May

Mar

Jan

0

Temperature (Fahrenheit)

Precipitation (mm)

Temperature

Mar

Month

Feb

Jan Mar May July Sept Nov

30°

Temperature (Fahrenheit)

Month

Use the information in Table 1 and the template be-

FIGURE 4 A line graph of Table 1

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Write the statement “3 is less than 5” in symbols. 2. What is the absolute value of a number? 3. Describe what we mean by numbers that are “opposites” of each other. Answer 9. See solutions section.

4. If you locate two different numbers on the number line, which one will be the smaller number?

7.1 Problem Set

Problem Set 7.1 A Write each of the following in words. [Example 1] 1. 4  7

2. 0  10

3. 5 2

4. 8 8

5. 10  3.

6. 20  5

7. 0 4

8. 0 100

Write each of the following in symbols.

9. 30 is greater than 30.

12. 0 is greater than 10.

10. 30 is less than 30.

11. 10 is less than 0.

13. 3 is greater than 15.

14. 15 is less than 3.

A Place either  or between each of the following pairs of numbers so that the resulting statement is true. [Examples 2–4] 15. 3

16. 17

7

19. 6

20. 14

0

1 2

6 7

23.  

3  4

24.  

27. 0.1

0.01

28. 0.04

31. 15

4

32. 20

5

17. 7

0

0

21. 12

5  6

25. 0.75

0.4

6

29. 3

18. 2

2

22. 20

0.25

26. 1

6

33. 2

13

30. 8

7

34. 3

1

3.5

2

1

B Find each of the following absolute values. [Examples 5–7] 35. 2

36. 7

37. 100

41. 231

42. 457

43. 

44. 

47. 8

48. 9

49. 231

50. 457

34

38. 10,000



1 10



39. 8

40. 9

45. 200

46. 350

463

464

Chapter 7 Introduction to Algebra

C Give the opposite of each of the following numbers. [Example 8] 51. 3

52. 5

53. 2

54. 15

55. 75

56. 32

57. 0

58. 1

59. 0.123

60. 3.45

61. 

7 8

62. 

1 100

Simplify each of the following.

63. (2)

64. (5)

65. (8)

66. (3)

67.  2

68.  5

69.  8

70.  3

71. What number is its own opposite?

72. Is a  a always a true statement?

73. If n is a negative number, is n positive or negative?

74. If n is a positive number, is n positive or negative?

Estimating Work Problems 75–80 mentally, without pencil and paper or a calculator.

75. Is 60 closer to 0 or 100?

76. Is 20 closer to 0 or 30?

77. Is 10 closer to 20 or 20?

78. Is 20 closer to 40 or 10?

79. Is 362 closer to 360 or 370?

80. Is 368 closer to 360 or 370?

7.1 Problem Set

D

Applying the Concepts

465

[Example 9]

81. The London Eye has a

82. The Eiffel Tower has sev-

height of 450 feet. De-

eral levels visitors can

scribe the location of

walk around on. The first

someone standing on the

is 57 meters above the

ground in relation to

ground, the second is 115

someone at the top of the

meters high, and the third

London Eye.

level is 276 meters high. What is the location of someone standing on the first level in relation to someone standing on the third level?

83. The Bright Angel trail at Grand Canyon National Park

84. The South Kaibab Trail at Grand Canyon National Park

ends at Indian Garden, 3,060 feet below the trailhead.

ends at Cedar Ridge, 1,140 feet below the trailhead.

Write this as a negative number with respect to the

Write this as a negative number with respect to the

trailhead.

trailhead.

85. Car Depreciation Depreciation refers to the decline in a car’s market value during the time you own the car. According to sources such as Kelley Blue Book and Edmunds.com, not all cars depreciate at the same rate. Suppose you pay $25,000 for a new car which has a high rate of depreciation. Your car loses about $5,000 in value per year. Represent this loss in value as a negative number. A car with a low rate of depreciation loses about $2,750 in value each year. Represent this loss as a negative number.

86. Census Figures In June, 2007 the U.S. Census Bureau re-

87. Temperature and Altitude Yamina is flying from Phoenix

88. Temperature Change At 11:00 in the morning in Superior,

leased population estimates for the twenty-five cities with the largest population loss between July 1, 2005 and July 1, 2006. New Orleans had the largest population loss. The city’s population fell by 228,782 people. Detroit, Michigan experienced a population loss of 12,344 people during the same time period. Represent the loss of population for New Orleans and for Detroit as a negative number.

to San Francisco on a Boeing 737 jet. When the plane

Wisconsin, Jim notices the temperature is 15 degrees

reaches an altitude of 33,000 feet, the temperature out-

below zero Fahrenheit. Write this temperature as a

side the plane is 61 degrees below zero Fahrenheit.

negative number. At noon it has warmed up by 8 de-

Represent this temperature with a negative number. If

grees. What is the temperature at noon?

the temperature outside the plane gets warmer by 10 degrees, what will the new temperature be?

466

Chapter 7 Introduction to Algebra

89. Temperature Change At 10:00 in the morning in White

90. Snorkeling Steve is snorkeling in the ocean near his

Bear Lake, Minnesota, Zach notices the temperature is

home in Maui. At one point he is 6 feet below the sur-

5 degrees below zero Fahrenheit. Write this tempera-

face. Represent this situation with a negative number.

ture as a negative number. By noon the temperature

If he descends another 6 feet, what negative number

has dropped another 10 degrees. What is the tempera-

will represent his new position?

ture at noon?

91. Time Zones New Orleans, Louisiana, is 1 time zone west

92. Time Zones Seattle, Washington, is 2 time zones west of

of New York City. Represent this time zone as a nega-

New Orleans, Louisiana. Represent this time zone as a

tive number, as discussed in the introduction to this

negative number, as discussed in the introduction to

chapter.

this chapter.

-11-10 -9 -8 -7 -6 -5 -4 -3 -2 -1 0 1 2 3 4 5 6 7 8 9 10 11 12

-11-10 -9 -8 -7 -6 -5 -4 -3 -2 -1 0 1 2 3 4 5 6 7 8 9 10 11 12

New Orleans, LA

Seatle, WA New Orleans, LA

New York, NY

Table 2 lists various wind chill temperatures. The top row gives air temperature, while the first column gives wind speed in miles per hour. The numbers within the table indicate how cold the weather will feel. For example, if the thermometer reads 30 F and the wind is blowing at 15 miles per hour, the wind chill temperature is 9 F.

TABLE 2

WIND CHILL TEMPERATURES Air temperatures (°F) Wind Speed 10 15 20 25 30

mph mph mph mph mph

30°

25°

20°

15°

10°

16° 9° 4° 1° 2°

10° 2° 3° 7° 10°

3° 5° 10° 15° 18°

3° 11° 17° 22° 25°

9° 18° 24° 29° 33°

93. Wind Chill Find the wind chill temperature if the ther-





5°

15° 25° 31° 36° 41°

22° 31° 39° 44° 49°

27° 38° 46° 51° 56°

94. Wind Chill Find the wind chill temperature if the ther-

mometer reads 25 F and the wind is blowing at 25

mometer reads 10 F and the wind is blowing at 25

miles per hour.

miles per hour.

95. Wind Chill Which will feel colder: a day with an air tem-

96. Wind Chill Which will feel colder: a day with an air tem-

perature of 10 F and a 25-mph wind, or a day with an

perature of 15 F and a 20-mph wind, or a day with an

air temperature of 5 F and a 10-mph wind?

air temperature of 5 F and a 10-mph wind?

467

7.1 Problem Set

Table 3 lists the record low temperatures for each month of the year for Lake Placid, New York. Table 4 lists the record high temperatures for the same city.

TABLE 3

TABLE 4

RECORD LOW TEMPERATURES FOR LAKE PLACID, NEW YORK

RECORD HIGH TEMPERATURES FOR LAKE PLACID, NEW YORK

Month

Temperature

Month

Temperature

January February March April May June July August September October November December

36°F 30°F 14°F 2°F 19°F 22°F 35°F 30°F 19°F 15°F 11°F 26°F

January February March April May June July August September October November December

54°F 59°F 69°F 82°F 90°F 93°F 97°F 93°F 90°F 87°F 67°F 60°F

97. Temperature Figure 5 is a bar chart of the information in Table 3. Use the template in Figure 6 to construct a scatter diagram of the same information. Then connect the dots in the scatter diagram to obtain a line graph of that same infor-

40°

40°

30°

30°

Temperature (Fahrenheit)

Temperature (Fahrenheit)

mation. (Notice that we have used the numbers 1 through 12 to represent the months January through December.)

20° 10° 0° -10° -20° -30°

20° 10° 0° -10° -20° -30° -40°

-40° -50° 1

2

3

4

5

6

7

8

9

10

11

12

2

1

3

4

5

Months

6

7

8

9

10

11

12

Months

FIGURE 6 A scatter diagram, then line graph of Table 3

FIGURE 5 A bar chart of Table 3

98. Temperature Figure 7 is a bar chart of the information in Table 4. Use the template in Figure 8 to construct a scatter diagram of the same information. Then connect the dots in the scatter diagram to obtain a line graph of that same information. (Again, we have used the numbers 1 through 12 to represent the months January through December.)

100° Temperature (Fahrenheit)

Temperature (Fahrenheit)

100° 80° 60° 40° 20° 0°

80° 60° 40° 20° 0°

1

2

3

4

5

6 7 Months

8

9

FIGURE 7 A bar chart of Table 4

10

11

12

1

2

3

4

5

6 7 Months

8

9

10

11

FIGURE 8 A scatter diagram, then line graph of Table 4

12

468

Chapter 7 Introduction to Algebra

Getting Ready for the Next Section Add or subtract.

99. 10  15

100. 12  15

101. 15  10

102. 15  12

103. 10  5  3  4

104. 12  3  7  5

105. [3  10]  [8  2]

106. [2  12]  [7  5]

107. 276  32  4,005

108. 17  3  152  1,200

109. 635  579

110. 2,987  1,130

Maintaining Your Skills Complete each statement using the commutative property of addition.

111. 3  5 

112. 9  x 

Complete each statement using the associative property of addition.

113. 7  (2  6) 

114. (x  3)  5 

Write each of the following in symbols.

115. The sum of x and 4

116. The sum of x and 4 is 9.

117. 5 more than y

118. x increased by 8

Extending the Concepts 119. There are two numbers that are 5 units from 2 on the number line. One of them is 7. What is the other one?

121. In your own words and in complete sentences, explain what the opposite of a number is.

123. The expression (3) is read “the opposite of negative 3,” and it simplifies to just 3. Give a similar written description of the expression  3 , and then simplify it.

120. There are two numbers that are 5 units from 2 on the number line. One of them is 3. What is the other one?

122. In your own words and in complete sentences, explain what the absolute value of a number is.

124. Give written descriptions of the expressions (4) and  4 and then simplify each of them.

Addition with Negative Numbers

7.2 Objectives A Use the number line to add positive

Introduction . . .

and negative numbers.

Suppose you are in Las Vegas playing blackjack and you lose $3 on the first hand and then you lose $5 on the next hand. If you represent winning with positive numbers and

J

results from your first two hands? Since you lost $3 and $5



for a total of $8, one way to represent the situation is with addition of negative numbers:



($3)  ($5)  $8

Add positive and negative numbers using a rule.

C

Solve applications involving addition with positive and negative numbers.

J

losing with negative numbers, how will you represent the

B

From this example we see that the sum of two negative numbers is a negative

Examples now playing at

number. To generalize addition of positive and negative numbers, we can use the

MathTV.com/books

number line.

A Adding with a Number Line We can think of each number on the number line as having two characteristics: (1) a distance from 0 (absolute value) and (2) a direction from 0 (positive or negative). The distance from 0 is represented by the numerical part of the number (like the 5 in the number 5), and its direction is represented by the  or  sign in front of the number. We can visualize addition of numbers on the number line by thinking in terms of distance and direction from 0. Let’s begin with a simple problem we know the answer to. We interpret the sum 3  5 on the number line as follows:

1. The first number is 3, which tells us “start at the origin, and move 3 units in the positive direction.”

2. The  sign is read “and then move.” 3. The 5 means “5 units in the positive direction.” Start

−8 −7 −6 −5 −4 −3 −2 −1

3 units

0

1

5 units

2

3

4

5

End

6

7

Note

This method of adding numbers may seem a little complicated at first, but it will allow us to add numbers we couldn’t otherwise add.

8

FIGURE 1 Figure 1 shows these steps. To summarize, 3  5 means to start at the origin (0), move 3 units in the positive direction, and then move 5 units in the positive direction. We end up at 8, which is the sum we are looking for: 3  5  8.

EXAMPLE 1 SOLUTION

PRACTICE PROBLEMS

Add 3  (5) using the number line.

1. Add: 2  (5)

We start at the origin, move 3 units in the positive direction, and

then move 5 units in the negative direction, as shown in Figure 2. The last arrow ends at 2, which must be the sum of 3 and 5. That is: 3  (5)  2 End

5 units Start

−8 −7 − 6 −5 − 4 −3 −2 −1

3 units

0

1

2

3

4

5

6

7

8 Answer 1. 3

FIGURE 2 7.2 Addition with Negative Numbers

469

470

2. Add: 2  5

Chapter 7 Introduction to Algebra

EXAMPLE 2 SOLUTION

Add 3  5 using the number line.

We start at the origin, move 3 units in the negative direction, and

then move 5 units in the positive direction, as shown in Figure 3. We end up at 2, which is the sum of 3 and 5. That is: 3  5  2

5 units

End

3 units 3 units

−8 −7 −6 −5 − 4 −3 −2 −1

Start

0

1

2

3

4

5

6

7

8

FIGURE 3

3. Add: 2  (5)

EXAMPLE 3 SOLUTION

Add 3  (5) using the number line.

We start at the origin, move 3 units in the negative direction, and

then move 5 more units in the negative direction. This is shown on the number line in Figure 4. As you can see, the last arrow ends at 8. We must conclude that the sum of 3 and 5 is 8. That is: 3  (5)  8

End

5 units

3 units

−8 −7 − 6 −5 − 4 −3 −2 −1

Start

0

1

2

3

4

5

6

7

8

FIGURE 4 Adding numbers on the number line as we have done in these first three examples gives us a way of visualizing addition of positive and negative numbers. We eventually want to be able to write a rule for addition of positive and negative numbers that doesn’t involve the number line. The number line is a way of justifying the rule we will eventually write. Here is a summary of the results we have so far: 3

58

3 

3  (5)  2

5

2

3  (5)  8

Examine these results to see if you notice any pattern in the answers.

4. Add: 2  6

EXAMPLE 4

4  7  11

Start

−7 − 6 −5 − 4 −3 −2 −1

Answers 2. 3 3. 7 4. 8

4 units

0

1

2

7 units

3

4

5

6

End

7

8

9 10 11

471

7.2 Addition with Negative Numbers

EXAMPLE 5

5. Add: 2  (6)

4  (7)  3

End

7 units Start

−9 −8 −7 − 6 −5 − 4 −3 −2 −1

EXAMPLE 6

34units units

0

1

2

3

6

7

8

9

6. Add: 2  6

End Start

3 units 4 units

−9 −8 −7 − 6 −5 − 4 −3 −2 −1

End

5

4  7  3

7 units

EXAMPLE 7

4

0

1

2

3

4

5

6

7

8

9

7. Add: 2  (6)

4  (7)  11

7 units

4 units

−11 −10 −9 −8 −7 − 6 −5 − 4 −3 −2 −1

Start

0

1

2

3

4

5

6

7

B Addition A summary of the results of these last four examples looks like this: 4

7  11

4  (7)  3 4 

7 

3

4  (7)  11 Looking over all the examples in this section, and noticing how the results in the problems are related, we can write the following rule for adding any two numbers:

Rule 1. To add two numbers with the same sign: Simply add their absolute values, and use the common sign. If both numbers are positive, the answer is positive. If both numbers are negative, the answer is negative.

2. To add two numbers with different signs: Subtract the smaller absolute

Note

This rule covers all possible addition problems involving positive and negative numbers. You must memorize it. After you have worked some problems, the rule will seem almost automatic.

value from the larger absolute value. The answer will have the sign of the number with the larger absolute value. Answers 5. 4 6. 4

7. 8

472

Chapter 7 Introduction to Algebra The following examples show how the rule is used. You will find that the rule for addition is consistent with all the results obtained using the number line.

8. Add all combinations of posi-

EXAMPLE 8

Add all combinations of positive and negative 10 and 15.

tive and negative 12 and 15.

SOLUTION

10 

15 

25

10  (15)  5 10 

15 

5

10  (15)  25 Notice that when we add two numbers with the same sign, the answer also has that sign. When the signs are not the same, the answer has the sign of the number with the larger absolute value. Once you have become familiar with the rule for adding positive and negative numbers, you can apply it to more complicated sums. 9. Simplify: 12  (3)  (7)  5

EXAMPLE 9 SOLUTION

Simplify: 10  (5)  (3)  4

Adding left to right, we have: 10  (5)  (3)  4  5  (3)  4 24

10  (5)  5 5  (3)  2

6

EXAMPLE 10

10. Simplify:

Simplify: [3  (10)]  [8  (2)]

[2  (12)]  [7  (5)]

SOLUTION

We begin by adding the numbers inside the brackets. [3  (10)]  [8  (2)]  [13]  [6]  7

11. Add: 5.76  (3.24)

EXAMPLE 11 SOLUTION

Add: 4.75  (2.25)

Because both signs are negative, we add absolute values. The an-

swer will be negative. 4.75  (2.25)  7.00

12. Add: 6.88  (8.55)

EXAMPLE 12 SOLUTION

Add: 3.42  (6.89)

The signs are different, so we subtract the smaller absolute value

from the larger absolute value. The answer will be negative, because 6.89 is larger than 3.42 and the sign in front of 6.89 is . 3.42  (6.89)  3.47 5 13. Add:     6



2 6



EXAMPLE 13 SOLUTION





1 3 Add:     8 8 3 We subtract absolute values. The answer will be positive, because 8

is positive.

Answers 8. See solutions section. 9. 7 10. 12 11. 9.00 12. 1.67 13.

1  2





2 3 1      8 8 8 1   4

Reduce to lowest terms

473

7.2 Addition with Negative Numbers

EXAMPLE 14 SOLUTION



 



4 3 1 Add:        5 20 10 To begin, change each fraction to an equivalent fraction with an

3 5 1 14. Add:      2

LCD of 20. 3 4 44 3 12 1                5 20 20 10  2 54 10



 







 

 

3 2 16       20 20 20



3 14     20 20







17   20

USING

TECHNOLOGY

Calculator Note There are a number of different ways in which calculators display negative numbers. Some calculators use a key labeled key labeled

/ , whereas others use a

() . You will need to consult with the manual that came with

your calculator to see how your calculator does the job. Here are a couple of ways to find the sum 10  (15) on a calculator: Scientific Calculator: 10 Graphing Calculator:

/ 

15

/ 

() 10  () 15 ENT

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Explain how you would use the number line to add 3 and 5. 2. If two numbers are negative, such as 3 and 5, what sign will their sum have? 3. If you add two numbers with different signs, how do you determine the sign of the answer? 4. With respect to addition with positive and negative numbers, does the phrase “two negatives make a positive” make any sense?

Answer 7 8

14. 

 4  8

This page intentionally left blank

7.2 Problem Set

475

Problem Set 7.2 A Draw a number line from 10 to 10 and use it to add the following numbers. [Examples 1–7] 1. 2  3

2. 2  (3)

3. 2  3

7. 4  (2)

8. 8  (2)

9. 10  (6)

13. 4  (5)

14. 2  (7)

4. 2  (3)

10. 9  3

5. 5  (7)

6. 5  7

11. 7  (3)

12. 7  3

B Combine the following by using the rule for addition of positive and negative numbers. (Your goal is to be fast and accurate at addition, with the latter being more important.) [Example 8]

15. 7  8

16. 9  12

17. 5  (8)

18. 4  (11)

19. 6  (5)

20. 7  (2)

21. 10  3

22. 14  7

23. 1  (2)

24. 5  (4)

25. 11  (5)

26. 16  (10)

27. 4  (12)

28. 9  (1)

29. 85  (42)

30. 96  (31)

31. 121  170

32. 130  158

33. 375  409

34. 765  213

Complete the following tables.

35.

37.

First Number a

Second Number b

5 5 5 5 5

3 4 5 6 7

First Number x

Second Number y

5 5 5 5 5

3 4 5 6 7

Their Sum ab

Their Sum xy

36.

38.

First Number a

Second Number b

5 5 5 5 5

3 4 5 6 7

First Number x

Second Number y

30 30 30 30 30

20 20 20 20 0

Their Sum ab

Their Sum xy

476

Chapter 7 Introduction to Algebra

B Add the following numbers left to right. [Example 9] 39. 24  (6)  (8)

40. 35  (5)  (30)

41. 201  (143)  (101)

42. 27  (56)  (89)

43. 321  752  (324)

44. 571  437  (502)

45. 2  (5)  (6)  (7)

46. 8  (3)  (4)  (7)

47. 15  (30)  18  (20)

48. 20  (15)  30  (18)

49. 78  (42)  57  13

50. 89  (51)  65  17

B Use the rule for order of operations to simplify each of the following. [Example 10] 51. (8  5)  (6  2)

52. (3  1)  (9  4)

53. (10  4)  (3  12)

54. (11  5)  (3  2)

55. 20  (30  50)  10

56. 30  (40  20)  50

57. 108  (456  275)

58. 106  (512  318)

59. [5  (8)]  [3  (11)]

60. [8  (2)]  [5  (7)]

61. [57  (35)]  [19  (24)]

62. [63  (27)]  [18  (24)]

Use the rule for addition of numbers to add the following fractions and decimals. [Examples 11–14]

63. 1.3  (2.5)

64. 9.1  (4.5)

65. 24.8  (10.4)

66. 29.5  (21.3)

67. 5.35  2.35  (6.89)

68. 9.48  5.48  (4.28)

5 6



1 6

11 13



12 13

69.     



72.    



7 9



2 9

70.     

2 5

3 5

3 7







5 7

71.    

4 5

73.       



6 7

4 7





1 7

74.       



7.2 Problem Set 75. 3.8  2.54  0.4

76. 9.6  5.15  0.8

78. 3.99  (1.42)  0.06

79.    

1 2



3 4

477

77. 2.89  (1.4)  0.09

3 5





7 10

80.    



63. Find the sum of 8, 10, and 3.

64. Find the sum of 4, 17, and 6.

65. What number do you add to 8 to get 3?

66. What number do you add to 10 to get 4?

67. What number do you add to 3 to get 7?

68. What number do you add to 5 to get 8?

69. What number do you add to 4 to get 3?

70. What number do you add to 7 to get 2?

71. If the sum of 3 and 5 is increased by 8, what number

72. If the sum of 9 and 2 is increased by 10, what num-

results?

C

ber results?

Applying the Concepts

81. One of the trails at the Grand Canyon starts at Bright

82. One of the trails in the Grand Canyon starts at the

Angel Trailhead and then drops 4,060 feet to the Col-

North Rim trailhead and drops 5,490 feet to the Col-

orado River and then climbs 4,440 feet to Yaki Point.

orado River. The trail then climbs 4,060 feet to the

What is the trail’s ending position in relation to the

Bright Angel Trailhead. What is the Bright Angel Trail-

Bright Angel Trailhead? If the trail ends below the start-

head’s position in relation to the North Rim Trailhead?

ing position write the answer as a negative number.

If the trail ends below the starting position write the answer as a negative number.

Yaki Point

North Rim Trailhead Bright Angel Trailhead

Yaki Point

Bright Angel Trailhead 4,060 ft

4,440 ft

4,060 ft

5,490 ft

Colorado River

Colorado River

North Rim Trailhead

478

Chapter 7 Introduction to Algebra

83. Checkbook Balance Ethan has a balance of $40 in his

84. Checkbook Balance Kendra has a balance of $20 in

checkbook. If he deposits $100 and then writes a

her checkbook. If she deposits $45 and then writes a

check for $50, what is the new balance in his check-

check for $15, what is the new balance in her check-

book?

book?

RECORD ALL CHARGES OR CREDITS

NUMBER

DATE

ITS THAT AFFECT YOUR ACCOUNT

THAT AFFECT YOUR ACCOUNT PAYMENT/DEBIT (-)

DESCRIPTION OF TRANSACTION

p it 9/20 Depos et arket ons MMark /21 VVons 150202 99/21

$$5050 0000

DEPOSIT/CREDIT (+)

100 00 $$100

BALANCE

-$$40 00 -$40

RECORD ALL CHARGES OR CRED NUMBER

DATE

PAYMENT/DEBIT (–)

DESCRIPTION OF TRANSACTION

p it 9/25 Depos Soccer 9/28 SSLOLO Socce 150404 9/28

$$115 0000

DEPOSIT/CREDIT (+)

$$4545 00

Getting Ready for the Next Section Give the opposite of each number.

85. 2

3 8

90. 

2 5

86. 3

87. 4

88. 5

89. 

91. 30

92. 15

93. 60.3

94. 70.4

95. Subtract 3 from 5.

96. Subtract 2 from 8.

97. Find the difference of 7 and 4.

98. Find the difference of 8 and 6.

Maintaining Your Skills The problems below review subtraction with whole numbers. Subtract.

99. 763  159

100. 1,007  136

101. 465  462  3

102. 481  479  2

Write each of the following statements in symbols.

103. The difference of 10 and x.

104. The difference of x and 10.

105. 17 subtracted from y.

106. y subtracted from 17.

BALANCE

-$$20 00

Subtraction with Negative Numbers

7.3 Objectives A Subtract numbers by thinking of

Introduction . . .

subtraction as addition of the opposite.

How would we represent the final balance in a checkbook if the original balance was $20 and we wrote a check for $30? The final balance would be $10. We can summarize the whole situation with subtraction: $20  $30  $10

RECORD ALL CHARGES OR CREDITS

NUMBER

DESCRIPTION OF TRANSACTION

DATE

1501 9/15 Campus Bookstore

B

Solve applications involving subtraction with positive and negative numbers.

THAT AFFECT YOUR ACCOUNT PAYMENT/DEBIT (-)

DEPOSIT/CREDIT (+)

$30 00

Examples now playing at

BALANCE

MathTV.com/books

$20 00 -$10 00

From this we see that subtracting 30 from 20 gives us 10. Another example that gives the same answer but involves addition is this: 20  (30)  10

A Subtraction From the two examples above, we find that subtracting 30 gives the same result as adding 30. We use this kind of reasoning to give a definition for subtraction that will allow us to use the rules we developed for addition to do our subtraction problems. Here is that definition:

Note

Definition Subtraction If a and b represent any two numbers, then it is always true that

88

8888

n

m88

a  b  a  (b)

To subtract b

Add its opposite, b

In words: Subtracting a number is equivalent to adding its opposite. Let’s see if this definition conflicts with what we already know to be true about

This definition of subtraction may seem a little strange at first. In Example 1 you will notice that using the definition gives us the same results we are used to getting with subtraction. As we progress further into the section, we will use the definition to subtract numbers we haven’t been able to subtract before.

subtraction.

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

Subtract: 5  2

1. Subtract: 7  3

From previous experience we know that 523

We can get the same answer by using the definition we just gave for subtraction. Instead of subtracting 2, we can add its opposite, 2. Here is how it looks: 5  2  5  (2) 3

Change subtraction to addition of the opposite Apply the rule for addition of positive and negative numbers

The result is the same whether we use our previous knowledge of subtraction or the new definition. The new definition is essential when the problems begin to get more complicated.

7.3 Subtraction with Negative Numbers

Answer 1. 4

479

480

2. Subtract: 7  3

Note

A real-life analogy to Example 2 would be: “If the temperature were 7 below 0 and then it dropped another 2 , what would the temperature be then?” 3. Subtract: 8  6

Chapter 7 Introduction to Algebra

EXAMPLE 2 SOLUTION

Subtract: 7  2

We have never subtracted a positive number from a negative num-

ber before. We must apply our definition of subtraction: 7  2  7  (2)  9

EXAMPLE 3 SOLUTION

Instead of subtracting 2, we add its opposite, 2 Apply the rule for addition

Subtract: 10  5

We apply the definition of subtraction (if you don’t know the defini-

tion of subtraction yet, go back and read it) and add as usual. 10  5  10  (5)  15

4. Subtract: 10  (6)

EXAMPLE 4 SOLUTION

Definition of subtraction Addition

Subtract: 12  (6)

The first  sign is read “subtract,” and the second one is read “nega-

tive.” The problem in words is “12 subtract negative 6.” We can use the definition of subtraction to change this to the addition of positive 6: 12  (6)  12  6  18

5. Subtract: 10  (15)

Note

Examples 4 and 5 may give results you are not used to getting. But you must realize that the results are correct. That is, 12  (6) is 18, and 20  (30) is 10. If you think these results should be different, then you are not thinking of subtraction correctly.

EXAMPLE 5 SOLUTION

Subtracting 6 is equivalent to adding 6 Addition

Subtract: 20  (30)

Instead of subtracting 30, we can use the definition of subtraction

to write the problem again as the addition of 30: 20  (30)  20  30  10

Definition of subtraction Addition

Examples 1–5 illustrate all the possible combinations of subtraction with positive and negative numbers. There are no new rules for subtraction. We apply the definition to change each subtraction problem into an equivalent addition problem. The rule for addition can then be used to obtain the correct answer.

6. Subtract each of the following. a. 8  5 b. 8  5 c. 8  (5) d. 8  (5) e. 12  10 f. 12  10 g. 12  (10) h. 12  (10)

Answers 2. 10 3. 14 4. 16 5. 5 6. a. 3 b. 13 c. 13 d. 3 e. 2 f. 22 g. 22 h. 2

EXAMPLE 6

The following table shows the relationship between sub-

traction and addition: Subtraction

Addition of the Opposite

Answer

79

7  (9)

2

7  9

7  (9)

16

7  (9)

79

16

7  (9)

7  9

2

15  10

15  (10)

5

15  10

15  (10)

25

15  (10)

15  10

25

15  (10)

15  10

5

481

7.3 Subtraction with Negative Numbers

EXAMPLE 7 SOLUTION

7. Combine: 4  6  7

Combine: 3  6  2

The first step is to change subtraction to addition of the opposite.

After that has been done, we add left to right. 3  6  2  3  6  (2)  3  (2)

Subtracting 2 is equivalent to adding 2 Add left to right

1

EXAMPLE 8 SOLUTION

Combine: 10  (4)  8

8. Combine: 15  (5)  8

Changing subtraction to addition of the opposite, we have 10  (4)  8  10  4  (8)  14  (8) 6

EXAMPLE 9 SOLUTION

Subtract 3 from 5.

9. Subtract 2 from 8.

Subtracting 3 is equivalent to adding 3. 5  3  5  (3)  8

Subtracting 3 from 5 gives us 8.

EXAMPLE 10 SOLUTION

Subtract 4 from 9.

10. Subtract 5 from 7.

Subtracting 4 is the same as adding 4: 9  (4)  9  4  13

Subtracting 4 from 9 gives us 13.

EXAMPLE 11 SOLUTION

Find the difference of 7 and 4.

11. Find the difference of 8 and 6.

Subtracting 4 from 7 looks like this: 7  (4)  7  4  3

The difference of 7 and 4 is 3.

EXAMPLE 12 SOLUTION

Subtract.

Subtract 60.3 from 49.8.

12. 57.8  70.4

49.8  60.3  49.8  (60.3)  110.1

EXAMPLE 13 SOLUTION

3 2 Find the difference of  and . 5 5

2 3 2 3        5 5 5 5



5   5  1

3 5 13.     8

8

 Answers 7. 5 8. 12 9. 10 10. 12 11. 2 12. 128.2 13. 1

482

Chapter 7 Introduction to Algebra

B Application

42 F at takeoff and then drops to 42 F when the plane reaches its cruising altitude. Find the difference in temperature at takeoff and at cruising altitude.

EXAMPLE 14

Many

of

the Courtesy of the U.S. Air Force Museum

14. Suppose the temperature is

planes used by the United States during World War II were not pressurized or sealed from outside air. As a result, the temperature inside these planes was the same as the surrounding air temperature outside. Suppose the temperature inside a B-17 Flying Fortress is 50 F at takeoff and then drops to 30 F

when the plane reaches its cruising altitude of 28,000 feet. Find the difference in temperature inside this plane at takeoff and at 28,000 feet.

SOLUTION

The temperature at takeoff is 50 F, whereas the temperature at

28,000 feet is 30 F. To find the difference we subtract, with the numbers in the same order as they are given in the problem: 50  (30)  50  30  80 The difference in temperature is 80 F.

Subtraction and Taking Away Some people may believe that the answer to 5  9 should be 4 or 4, not 14. If this is happening to you, you are probably thinking of subtraction in terms of taking one number away from another. Thinking of subtraction in this way works well with positive numbers if you always subtract the smaller number from the larger. In algebra, however, we encounter many situations other than this. The definition of subtraction, that a  b  a  (b) clearly indicates the correct way to use subtraction. That is, when working subtraction problems, you should think “addition of the opposite,” not “taking one number away from another.”

USING

TECHNOLOGY

Calculator Note Here is how we work the subtraction problem shown in Example 11 on a calculator. Scientific Calculator: 7 Graphing Calculator:

/ 

4

/ 

() 7  () 4 ENT

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Write the subtraction problem 5  3 as an equivalent addition problem. 2. Explain the process you would use to subtract 2 from 7. 3. Write an addition problem that is equivalent to the subtraction problem 20  (30). Answer 14. 84 F

4. To find the difference of 7 and 4 we subtract what number from 7?

7.3 Problem Set

Problem Set 7.3 A Subtract. [Examples 1–5] 1. 7  5

2. 5  7

3. 8  6

4. 6  8

5. 3  5

6. 5  3

7. 4  1

8. 1  4

10. 2  (5)

11. 3  (9)

12. 9  (3)

13. 4  (7)

14. 7  (4)

15. 10  (3)

16. 3  (10)

17. 15  18

18. 20  32

19. 100  113

20. 121  21

21. 30  20

22. 50  60

23. 79  21

24. 86  31

25. 156  (243)

26. 292  (841)

27. 35  (14)

28. 29  (4)

29. 9.01  2.4

30. 8.23  5.4

31. 0.89  1.01

32. 0.42  2.04

9. 5  (2)

1 6

5 6

33.   

13 70

23 42

37.   

4 7

3 7

34.   

17 60

17 90

38.   

5 12

5 6

35.   

7 15

4 5

36.   

483

484

Chapter 7 Introduction to Algebra

A Simplify as much as possible by first changing all subtractions to addition of the opposite and then adding left to right. [Examples 7, 8] 39. 4  5  6

40. 7  3  2

41. 8  3  4

42. 10  1  16

43. 8  4  2

44. 7  3  6

45. 12  30  47

46. 29  53  37

47. 33  (22)  66

48. 44  (11)  55

49. 101  (95)  6

50. 211  (207)  3

51. 900  400  (100)

52. 300  600  (200)

53. 3.4  5.6  8.5

54. 2.1  3.1  4.1

1 2

1 3

1 4

1 5

55.     

1 6

1 7

56.     

A Translate each of the following and simplify the result. [Examples 9–11] 57. Subtract 6 from 5.

58. Subtract 8 from 2.

59. Find the difference of 5 and 1.

60. Find the difference of 7 and 3.

61. Subtract 4 from the sum of 8 and 12.

62. Subtract 7 from the sum of 7 and 12.

63. What number do you subtract from 3 to get 9?

64. What number do you subtract from 5 to get 8?

Estimating Work Problems 55–60 mentally, without pencil and paper or a calculator.

65. The answer to the problem 52  49 is closest to which of the following numbers?

a. 100

b. 0

which of the following numbers?

c. 100

67. The answer to the problem 52  (49) is closest to which of the following numbers?

a. 100

b. 0

66. The answer to the problem 52  49 is closest to

c. 100

69. Is 161  (62) closer to 200 or 100?

a. 100

b. 0

c. 100

68. The answer to the problem 52  (49) is closest to which of the following numbers?

a. 100

b. 0

c. 100

70. Is 553  50 closer to 600 or 500?

7.3 Problem Set

B

Applying the Concepts

485

[Example 12]

71. The graph shows the record low temperatures for the

72. The graph shows the lowest and highest points in the

Grand Canyon. What is the temperature difference be-

Grand Canyon and Death Valley. What is the difference

tween January and July?

between the lowest point in the Grand Canyon and the lowest point in Death Valley?

Lowest and Highest Points

Record Low Temperatures Temperature (Celsius)

8˚ Point Imperial 8,803

Grand Canyon



Lake Mead 1,200

0˚ –4˚

Telescope Peak 11,049

Death Valley

Badwater Basin –282

–8˚ 0

JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC

5,000 10,000 Elevation (feet)

15,000

Source: National Park Service

Source: National Park Service

73. The highest point in Grand Canyon National Park is at

74. Temperature On Monday the temperature reached a

Point Imperial with an elevation of 8,803 feet. The low-

high of 28 above 0. That night it dropped to 16 below

est point in the park is at Lake Mead at 1,200 feet.

0. What is the difference between the high and the low

What is the difference between the highest and the

temperatures for Monday?

lowest points?

75. Tracking Inventory By definition, inventory is the total

76. Profit and Loss You own a small business which pro-

amount of goods contained in a store or warehouse at

vides computer support to homeowners who wish to

any given time. It is helpful for store owners to know

create their own in-house computer network. In addi-

the number of items they have available for sale in or-

tion to setting up the network you also maintain and

der to accommodate customer demand. This table

troubleshoot home PCs. Business gets off to a slow

shows the beginning inventory on May 1st and tracks

start. You record a profit of $2,298 during the first quar-

the number of items bought and sold for one month.

ter of the year, a loss of $2,854 during the second quar-

Determine the number of items in inventory at the end

ter, a profit of $3,057 during the third quarter, and a

of the month.

profit of $1,250 for the last quarter of the year. Do you end the year with a net profit or a net loss? Represent

Date

Transaction

May 1 May 3 May 8 May 15 May 19 May 25 May 27 May 31

Beginning Inventory Purchase Sale Purchase Purchase Sale Sale Ending Inventory

Number of Units Available

Number of Units Sold

400 100 700 600 200 400 300

that profit or loss as a positive or negative value.

486

Chapter 7 Introduction to Algebra

Tuition Cost The chart shows the cost of college tuition and fees at public four-year universities. Because of tax breaks, along with federal and state grants, the actual cost per student is much less than the total cost of tuition and fees. Use the information in this chart to answers Questions 67 through 70.

77. Find the difference in student grants in 1998 and student

Tuition and Fees at 4-year Public Universities

grants and tax deductions in 2008.

Actual cost Student grants

78. Find the difference in actual costs in 1998 and actual costs in

1998

$1,636

$1,940

$3,576

2008. 2008

79. Find the difference in total costs in 1998 and total costs in

Actual cost

Tax deductions/ grants

$2,885

$3,700

$6,585 Sources: College Board

2008.

80. What has increased more from 1998 to 2008, student grants and tax deductions or actual student costs?

Repeated below is the table of wind chill temperatures that we used previously. Use it for Problems 81–84. Air Temperature (°F) Wind speed 10 15 20 25 30

mph mph mph mph mph

30° 16° 9° 4° 1° 2°

25°

20°

15°

10°





5°

10° 2° 3° 7° 10°

3° 5° 10° 15° 18°

3° 11° 17° 22° 25°

9° 18° 24° 29° 33°

15° 25° 31° 36° 41°

22° 31° 39° 44° 49°

27° 38° 46° 51° 56°

81. Wind Chill If the temperature outside is 15 F, what is the

82. Wind Chill If the temperature outside is 0 F, what is the

difference in wind chill temperature between a 15-

difference in wind chill temperature between a 15-

mile-per-hour wind and a 25-mile-per-hour wind?

mile-per-hour wind and a 25-mile-per-hour wind?

83. Wind Chill Find the difference in temperature between a

84. Wind Chill Find the difference in temperature between a

day in which the air temperature is 20 F and the wind is

day in which the air temperature is 0 F and the wind is

blowing at 10 miles per hour and a day in which the air

blowing at 10 miles per hour and a day in which the air

temperature is 10 F and the wind is blowing at 20 miles

temperature is 5 F and the wind is blowing at 20

per hour.

miles per hour.

7.3 Problem Set

487

Use the tables below to work Problems 85–88. RECORD LOW TEMPERATURES FOR LAKE PLACID, NEW YORK

RECORD HIGH TEMPERATURES FOR LAKE PLACID, NEW YORK

Month

Temperature

Month

Temperature

January February March April May June July August September October November December

36 F 30 F 14 F 2 F 19 F 22 F 35 F 30 F 19 F 15 F 11 F 26 F

January February March April May June July August September October November December

54 F 59 F 69 F 82 F 90 F 93 F 97 F 93 F 90 F 87 F 67 F 60 F

85. Temperature Difference Find the difference between the

86. Temperature Difference Find the difference between the

record high temperature and the record low tempera-

record high temperature and the record low tempera-

ture for the month of December.

ture for the month of March.

87. Temperature Difference Find the difference between the

88. Temperature Difference Find the difference between the

record low temperatures of March and December.

record high temperatures of March and December.

Getting Ready for the Next Section Perform the indicated operations.

89. 3(2)(5)

90. 5(2)(4)

91. 62

92. 82

93. 43

94. 33

95. 6(3  5)

96. 2(5  8)

97. 3(9  2)  4(7  2)

98. 2(5  3)  7(4  2)

99. (3  7)(6  2)

100. (6  1)(9  4)

Simplify each of the following.

101. 2  3(4  1)

102. 6  5(2  3)

103. (6  2)(6  2)

104. (7  1)(7  1)

105. 52

106. 23

107. 23  32

108. 23  32

488

Chapter 7 Introduction to Algebra

Maintaining Your Skills Write each of the following in symbols.

109. The product of 3 and 5.

110. The product of 5 and 3.

111. The product of 7 and x.

112. The product of 2 and y.

Rewrite the following using the commutative property of multiplication.

113. 3(5) 

114. 7(x) 

Rewrite the following using the associative property of multiplication.

115. 5(7  8) 

116. 4(6  y)

Apply the distributive property to each expression and then simplify the result.

117. 2(3  4)

118. 5(6  7)

Extending the Concepts 119. Give an example that shows that subtraction is not a

120. Why is the expression “two negatives make a positive”

commutative operation.

121. Give an example of an everyday situation that is mod-

not correct?

122. Give an example of an everyday situation that is mod-

eled by the subtraction problem

eled by the subtraction problem

$10  $12  $2.

$10  $12  $22.

In Chapter 1 we defined an arithmetic sequence as a sequence of numbers in which each number, after the first number, is obtained from the previous number by adding the same amount each time. Find the next two numbers in each arithmetic sequence below.

123. 10, 5, 0, . . .

124. 8, 3, 2, . . .

125. 10, 6, 2, . . .

126. 4, 1, 2, . . .

Multiplication with Negative Numbers

7.4 Objectives A Multiply positive and negative

Introduction . . .

numbers.

Suppose you buy three shares of a certain stock on Monday, and by Friday the price per share has

B

Apply the rule for order of operations to expressions containing positive and negative numbers.

C

Solve applications involving multiplication with positive and negative numbers.

dropped $5. How much money have you lost? The answer is $15. Because it is a loss, we can express it as $15. The multiplication problem below can be used to describe the relationship among the numbers.

3 shares

each loses $5 88n

88n

888

for a total of $15

3(5)  15

88

88

m

Examples now playing at

From this we conclude that it is reasonable to say that the product of a positive

MathTV.com/books

number and a negative number is a negative number.

A Multiplication In order to generalize multiplication with negative numbers, recall that we first defined multiplication by whole numbers to be repeated addition. That is: 35555 h h h

Multiplication

Repeated addition

This concept is very helpful when it comes to developing the rule for multiplication problems that involve negative numbers. For the first example we look at what happens when we multiply a negative number by a positive number.

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

1. Multiply: 2(6)

Multiply: 3(5)

Writing this product as repeated addition, we have 3(5)  (5)  (5)  (5)  10  (5)  15

The result, 15, is obtained by adding the three negative 5’s.

EXAMPLE 2 SOLUTION

2. Multiply: 2(6)

Multiply: 3(5)

In order to write this multiplication problem in terms of repeated

addition, we will have to reverse the order of the two numbers. This is easily done, because multiplication is a commutative operation. 3(5)  5(3)  (3)  (3)  (3)  (3)  (3)  15

Commutative property Repeated addition Addition

The product of 3 and 5 is 15.

EXAMPLE 3 SOLUTION

3. Multiply: 2(6)

Multiply: 3(5)

It is impossible to write this product in terms of repeated addition.

We will find the answer to 3(5) by solving a different problem. Look at the folAnswers 1. 12 2. 12

lowing problem: 3[5  (5)]  3[0]  0

7.4 Multiplication with Negative Numbers

489

490

Note

The discussion here explains why 3(5)  15. We want to be able to justify everything we do in mathematics. The discussion tells why 3(15)  15.

Chapter 7 Introduction to Algebra The result is 0, because multiplying by 0 always produces 0. Now we can work the same problem another way, and in the process find the answer to 3(5). Applying the distributive property to the same expression, we have 3[5  (5)]  3(5)  (3)(5)  15  (?)

Distributive property 3(5)  15

The question mark must be 15, because we already know that the answer to the problem is 0, and 15 is the only number we can add to 15 to get 0. So, our problem is solved: 3(5)  15 Table 1 gives a summary of what we have done so far in this section. TABLE 1

Original Numbers Have Same signs Different signs Different signs Same signs

For Example

The Answer Is

3(5)  15 3(5)  15 3(5)  15 3(5)  15

Positive Negative Negative Positive

From the examples we have done so far in this section and their summaries in Table 1, we write the following rule for multiplication of positive and negative numbers:

Rule To multiply any two numbers, we multiply their absolute values.

1. The answer is positive if both the original numbers have the same sign. That is, the product of two numbers with the same sign is positive.

2. The answer is negative if the original two numbers have different signs. The product of two numbers with different signs is negative. This rule should be memorized. By the time you have finished reading this section and working the problems at the end of the section, you should be fast and accurate at multiplication with positive and negative numbers. Multiply. 4. 3(2)

EXAMPLE 4

5. 3(2)

EXAMPLE 5

6. 3(2)

EXAMPLE 6

2(4)  8

Like signs; positive answer

2(4)  8

Like signs; positive answer

2(4)  8

Unlike signs; negative answer

2(4)  8

Unlike signs; negative answer

7. 3(2) 8. 8(9)

EXAMPLE 7

9. 6(4)

EXAMPLE 8

10. 5(2)(4)

EXAMPLE 9

Answers 3. 12 4. 6 5. 6 6. 6 7. 6 8. 72 9. 24 10. 40

EXAMPLE 10

7(6)  42

Unlike signs; negative answer

5(8)  40

Like signs; positive answer

3(2)(5)  6(5)  30

Multiply 3 and 2 to get 6

491

7.4 Multiplication with Negative Numbers

EXAMPLE 11

Use the definition of exponents to expand each expres-

sion. Then simplify by multiplying.

a. (6)2  (6)(6)  36

b.

62  6  6  36

c. (4)3  (4)(4)(4)  64

d.

43  4  4  4  64

Definition of exponents Multiply Definition of exponents Multiply Definition of exponents Multiply Definition of exponents Multiply

11. Use the definition of exponents to expand each expression. Then simplify by multiplying. a. (8)2

b. 82 c. (3)3 d. 33

In Example 11, the base is a negative number in Parts a and c, but not in Parts b and d. We know this is true because of the use of parentheses.

B Order of Operations EXAMPLE 12 SOLUTION

12. Simplify: 2[5  (8)]

Simplify: 6[3  (5)]

We begin inside the brackets and work our way out: 6[3  (5)]  6[2]  12

EXAMPLE 13 SOLUTION

Simplify: 4  5(6  2)

Simplifying inside the parentheses first, we have 4  5(6  2)  4  5(4)  4  (20)  24

EXAMPLE 14 SOLUTION

13. Simplify: 3  4(7  3)

Simplify inside parentheses Multiply Add

Simplify: 2(7)  3(6)

14. Simplify: 3(5)  4(4)

Multiplying left to right before we add gives us 2(7)  3(6)  14  (18)  32

EXAMPLE 15 SOLUTION

Simplify: 3(2  9)  4(7  2)

15. Simplify: 2(3  5)  7(2  4)

We begin by subtracting inside the parentheses: 3(2  9)  4(7  2)  3(7)  4(9)  21  (36)  15

EXAMPLE 16 SOLUTION

Simplify: (3  7)(2  6)

16. Simplify: (6  1)(4  9)

Again, we begin by simplifying inside the parentheses: (3  7)(2  6)  (10)(4)  40

Answers 11. a. 64 b. 64 c. 27 d. 27 12. 6 13. 19 14. 31 15. 46 16. 35

492

Chapter 7 Introduction to Algebra

USING

TECHNOLOGY

Calculator Note Here is how we work the problem shown in Example 16 on a calculator. (The



key on the first line may, or may not, be necessary. Try your calcula-

tor without it and see.) Scientific Calculator: Graphing Calculator:

/  7 )  ( 2  6 )  ( () 3  7 ) ( 2  6 ) ENT (

3

Here are a few more multiplication problems involving fractions and decimals. 3 4

4

 7

17.  

5

 6 

9 20

18.  



EXAMPLE 17

   3  5     15 5

EXAMPLE 18

   8   14  112 16

EXAMPLE 19

19. (3)(6.7)

2

3

7

6

5

35

2

The rule for multiplication also holds for fractions

5

(5)(3.4)  17.0 The rule for multiplication also holds for

decimals

20. (0.6)(0.5)

EXAMPLE 20

(0.4)(0.8)  0.32

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Write the multiplication problem 3(5) as an addition problem. 2. Write the multiplication problem 2(4) as an addition problem. 3. If two numbers have the same sign, then their product will have what sign? 4. If two numbers have different signs, then their product will have what sign?

Answers 3 7 20. 0.30

3 8

17.  18.  19. 20.1

7.4 Problem Set

493

Problem Set 7.4 A Find each of the following products. (Multiply.) [Examples 1–10] 1. 7(8)

2. 3(5)

3. 6(10)

4. 4(8)

5. 7(8)

6. 4(7)

7. 9(9)

8. 6(3)

9. 2.1(4.3)

4 5

5

2

3

15 28



11.    

10. 6.8(5.7)

6

8 9





27 32

12.    



13. 12 

14. 18 

15. 3(2)(4)

16. 5(1)(3)

17. 4(3)(2)

18. 4(5)(6)

19. 1(2)(3)

20. 2(3)(4)

Use the definition of exponents to expand each of the following expressions. Then multiply according to the rule for multiplication. [Example 11]

21. a. (4)2 b. 42

22. a. (5)2

23. a. (5)3

b. 52

24. a. (4)3

b. 53

25. a. (2)4

b. 43

26. a. (1)4

b. 24

b. 14

Complete the following tables. Remember, if x  5, then x2  (5)2  25. [Example 11]

27.

Number x

28.

Square x2

Cube x3

3 2 1 0 1 2 3

3 2 1 0 1 2 3

29.

Number x

First Number x

Second Number y

6 6 6 6 6

2 1 0 1 2

Their Product xy

30.

First Number a

Second Number b

5 5 5 5 5 5 5

3 2 1 0 1 2 3

Their Product ab

494

Chapter 7 Introduction to Algebra

B Use the rule for order of operations along with the rules for addition, subtraction, and multiplication to simplify each of the following expressions. [Examples 12–16]

31. 4(3  2)

32. 7(6  3)

33. 10(2  3)

34. 5(6  2)

35. 3  2(5  3)

36. 7  3(6  2)

37. 7  2[5  9]

38. 8  3[4  1]

39. 2(5)  3(4)

40. 6(1)  2(7)

41. 3(2)4  3(2)

42. 2(1)(3)  4(6)

43. (8  3)(2  7)

44. (9  3)(2  6)

45. (2  5)(3  6)

46. (3  7)(2  8)

47. 3(5  8)  4(6  7)

48. 2(3  7)  3(5  6)

49. 2(8  10)  3(4  9)

50. 3(6  9)  2(3  8)

51. 3(4  7)  2(3  2)

52. 5(2  8)  4(6  10)

53. 3(2)(6  7)

54. 4(3)(2  5)

55. Find the product of 3, 2, and 1.

56. Find the product of 7, 1, and 0.

57. What number do you multiply by 3 to get 12?

58. What number do you multiply by 7 to get 21?

59. Subtract 3 from the product of 5 and 4.

60. Subtract 5 from the product of 8 and 1.

Work Problems 61–68 mentally, without pencil and paper or a calculator.

61. The product 32(522) is closest to which of the following numbers?

a. 15,000

b. 500

ing numbers?

c. 1,500

d. 15,000

63. The product 47(470) is closest to which of the following numbers?

a. 25,000

c. 2,500

d. 25,000

lowing numbers?

b. 800

b. 500

c. 1,500

d. 15,000

64. The product 47(470) is closest to which of the fol-

d. 1,200

following numbers?

b. 800

a. 25,000

b. 420

c. 2,500

d. 25,000

66. The sum 222  (987) is closest to which of the following numbers?

c. 800

67. The difference 222  (987) is closest to which of the a. 200,000

a. 15,000

lowing numbers?

b. 420

65. The product 222(987) is closest to which of the fola. 200,000

62. The product 32(522) is closest to which of the follow-

a. 200,000

b. 800

c. 800

d. 1,200

68. The difference 222  987 is closest to which of the following numbers?

c. 800

d. 1,200

a. 200,000

b. 800

c. 800

d. 1,200

495

7.4 Problem Set

C

Applying the Concepts

69. The chart shows the record low temperatures for Grand Canyon National Park, by month. Write the record low

70. The chart shows the cities with the highest annual insurance rates.

temperature for March.

Priciest Cities for Auto Insurance Record Low Temperatures Detroit Temperature (Celsius)



$5,894

Philadelphia



Newark, N.J.



Los Angeles

$4,440 $3,977 $3,430

New York City

–4˚

$3,303 0

$1000

$2000

$3000

$4000

$5000

$6000

–8˚ JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC

Source: Runzheimer International

Source: National Park Service

a. What is the monthly payment for a driver in Philadelphia?

b. Use negative numbers to write an expression for the cost of three months of auto insurance for a driver living in Philadelphia.

71. Temperature Change A hot-air balloon is rising to its

72. Temperature Change A small airplane is rising to its

cruising altitude. Suppose the air temperature around

cruising altitude. Suppose the air temperature around

the balloon drops 4 degrees each time the balloon rises

the plane drops 4 degrees each time the plane in-

1,000 feet. What is the net change in air temperature

creases its altitude by 1,000 feet. What is the net

around the balloon as it rises from 2,000 feet to 6,000

change in air temperature around the plane as it rises

feet?

from 5,000 feet to 12,000 feet?

12,000 ft

6,000 ft 5,000 ft

2,000 ft

73. Expense Account A business woman has a travel ex-

74. Gas Prices Two local gas stations offer different prices

pense account of $1,000. If she spends $75 a week for 8

for a gallon of regular gasoline. The Exxon Mobil sta-

weeks what will the balance of her expense account be

tion is currently selling their gas at $3.99 per gallon.

at the end of this time.

The Getty station is currently selling their gas for $3.85 per gallon. Represent the net savings to you on a purchase of 15 gallons of regular gas if you buy gas from the Getty gas station.

496

Chapter 7 Introduction to Algebra

Getting Ready for the Next Section Perform the indicated operations. 20 4

30 5

75. 35  5

76. 32  4

77. 

78. 

79. 12  17

80. 7  11

81. (6  3)  2

82. (8  5)  4

83. 80  10  2

84. 80  2  10

85. 15  5(4)  10

86. [20  6(2)]  (11  7)

87. 4(102)  20  4

88. 3(42)  10  5

Maintaining Your Skills Write each of the following statements in symbols.

89. The quotient of 12 and 6

90. The quotient of x and 5

Rewrite each of the following multiplication problems as an equivalent division problem.

91. 2(3)  6

92. 5  4  20

Rewrite each of the following division problems as an equivalent multiplication problem. 63 9

93. 10  5  2

94.   7

Divide.

95. 4,984  56

96. 4,994  56

Extending the Concepts In Chapter 1 we defined a geometric sequence to be a sequence of numbers in which each number, after the first number, is obtained from the previous number by multiplying by the same amount each time. Find the next two terms in each of the following geometric sequences.

97. 2, 6, 18, . . .

98. 1, 4, 16, . . .

99. 2, 6, 18, . . .

100. 1, 4, 16, . . .

Simplify each of the following according to the rule for order of operations.

101. 5(2)2  3(2)3

102. 8(1)3  6(3)2

103. 7  3(4  8)

104. 6  2(9  11)

105. 5  2[3  4(6  8)]

106. 7  4[6  3(2  9)]

Division with Negative Numbers

7.5 Objectives A Divide positive and negative

Introduction . . .

numbers.

Suppose four friends invest equal amounts of money in a moving truck to start a small busi-

B

Apply the rule for order of operations to expressions that contain positive and negative numbers.

C

Solve applications involving division with positive and negative numbers.

MOVERS

ness. After 2 years the truck has dropped $10,000 in value. If we represent this change with the number $10,000, then the loss to each of the four partners can be found with division:

$10,000 drop in 2 years

($10,000)  4  $2,500

From this example it seems reasonable to assume that a negative number divided by a positive number will give a negative answer. To cover all the possible situations we can encounter with division of negative

Examples now playing at

numbers, we use the relationship between multiplication and division. If we let n

MathTV.com/books

be the answer to the problem 12  (2), then we know that 12  (2)  n

2(n)  12

and

From our work with multiplication, we know that n must be 6 in the multiplication problem above, because 6 is the only number we can multiply 2 by to get 12. Because of the relationship between the two problems above, it must be true that 12 divided by 2 is 6. The following pairs of problems show more quotients of positive and negative numbers. In each case the multiplication problem on the right justifies the answer to the division problem on the left. because

3(2)  6

6  (3)  2

632

because

3(2)  6

6  3  2

because

3(2)  6

because

3(2)  6

6  (3)  2

The results given above can be used to write the rule for division with negative numbers.

A Division Rule To divide two numbers, we divide their absolute values.

1. The answer is positive if both the original numbers have the same sign. That is, the quotient of two numbers with the same signs is positive.

2. The answer is negative if the original two numbers have different signs. That is, the quotient of two numbers with different signs is negative.

PRACTICE PROBLEMS Divide.

EXAMPLE 1 EXAMPLE 2 EXAMPLE 3

12  4  3

Unlike signs, negative answer

1. 8  2 2. 8  (2)

12  (4)  3

Unlike signs; negative answer

12  (4)  3

Like signs; positive answer

3. 8  (2) 20 5

4.  30 5

5. 

EXAMPLE 4

12   3 4

Unlike signs; negative answer

EXAMPLE 5

20   5 4

Like signs; positive answer 7.5 Division with Negative Numbers

Answers 1. 4 2. 4 3. 4 4. 4 5. 6

497

498

Chapter 7 Introduction to Algebra From the examples we have done so far, we can make the following generalization about quotients that contain negative signs:

If a and b are numbers and b is not equal to 0, then a a a a a      and    b b b b b

B Order of Operations The last examples in this section involve more than one operation. We use the rules developed previously in this chapter and the rule for order of operations to simplify each. 8(5) 4

6. Simplify: 

EXAMPLE 6 SOLUTION

6(3) Simplify:  2 We begin by multiplying 6 and 3: 6(3) 18     2 2 9

20  6(2) 7  11

7. Simplify: 

Multiplication; 6(3)  18 Like signs; positive answer

EXAMPLE 7 SOLUTION

15  5(4) Simplify:   12  17 Simplifying above and below the fraction bar, we have 15  5(4) 15  (20) 35         7 12  17 5 5

8. Simplify: 3(42)  10  (5)

EXAMPLE 8 SOLUTION

Simplify: 4(102)  20  (4)

Applying the rule for order of operations, we have 4(102)  20  (4)  4(100)  20  (4)  400  (5)  405

9. Simplify: 80  2  10

EXAMPLE 9 SOLUTION

Exponents first Multiply and divide Add

Simplify: 80  10  2

In a situation like this, the rule for order of operations states that we

are to divide left to right. 80  10  2  8  2

Divide 80 by 10

 4

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Write a multiplication problem that is equivalent to the division problem 12  4  3. 2. Write a multiplication problem that is equivalent to the division problem 12  (4)  3.

Answers 6. 10 7. 8 8. 50 9. 4

3. If two numbers have the same sign, then their quotient will have what sign? 4. Dividing a negative number by 0 always results in what kind of expression?

7.5 Problem Set

Problem Set 7.5 A Find each of the following quotients. (Divide.) [Examples 1–5] 1. 15  5

2. 15  (3)

3. 20  (4)

5. 30  (10)

6. 50  (25)

7. 

9. 

12 3

10. 

0 3

14. 

13. 

4. 20  4

14 7

18 6

8. 

12 4

11. 22  11

12. 35  7

0 5

15. 125  (25)

16. 144  (9)

Complete the following tables.

17.

19.

First Number

Second Number

a

b

100 100 100 100

5 10 25 50

First Number

Second Number

a

b

100 100 100 100

The Quotient of a and b a  b

18.

First Number

Second Number

a

b

24 24 24 24

The Quotient of a and b a  b

5 5 5 5

20.

4 3 2 1

First Number

Second Number

a

b

24 24 24 24

The Quotient of a and b a  b

The Quotient of a and b a  b

2 4 6 8

21. Find the quotient of 25 and 5.

22. Find the quotient of 38 and 19.

23. What number do you divide by 5 to get 7?

24. What number do you divide by 6 to get 7?

25. Subtract 3 from the quotient of 27 and 9.

26. Subtract 7 from the quotient of 72 and 9.

499

500

Chapter 7 Introduction to Algebra

B Use any of the rules developed in this chapter and the rule for order of operations to simplify each of the following expressions as much as possible. [Examples 6–9] 3(10) 5

30. 

48 84

34. 

2  3(6) 4  12

38. 

41. 

3(7)(4) 6(2)

42. 

44. 62  36  9

45. 100  (5)2

46. 400  (4)2

47. 100  10  2

48. 500  50  10

49. 100  (10  2)

50. 500  (50  10)

51. (100  10)  2

52. (500  50)  10

27. 

4(7) 28

28. 

6(3)  18

29. 

2(3) 63

32. 

2(3) 36

33. 

2(3)  10 4

36. 

7(2)  6 10

37. 

39. 

6(7)  3(2) 20  4

40. 

9(8)  5(1) 12  1

43. (5)2  20  4

31. 

35. 

4(12) 6

95 59

3  9(1) 57

2(4)(8) (2)(2)

Estimating Work Problems 53–60 mentally, without pencil and paper or a calculator.

53. Is 397  (401) closer to 1 or 1?

54. Is 751  (749) closer to 1 or 1?

55. The quotient 121  27 is closest to which of the fol-

56. The quotient 1,000  (337) is closest to which of the

lowing numbers?

a. 150

b. 100

following numbers?

c. 4

d. 6

a. 663

b. 3

c. 30

d. 663

57. Which number is closest to the sum 151  (49)? a. 200 b. 100 c. 3 d. 7,500

58. Which number is closest to 151  (49)? a. 200 b. 100 c. 3 d. 7,500

59. Which number is closest to the product 151(49)? a. 200 b. 100 c. 3 d. 7,500

60. Which number is closest to the quotient 151  (49)? a. 200 b. 100 c. 3 d. 7,500

7.5 Problem Set

C

501

Applying the Concepts

61. The chart shows the most expensive cities to live in.

62. The chart shows the cities with the most expensive

Expenses can also be written as negative numbers.

auto insurance. Because insurance is an expense, it

Find the monthly cost to live in Los Angeles. Use nega-

can be written as a negative number. What is the

tive numbers.

monthly cost of insurance in New York City? Use negative numbers and round to the nearest cent.

Priciest Cities for Auto Insurance

Priciest Cities to Inhabit in the U.S.

Los Angeles San Jose Washington, D.C.

Detroit

S146,060

Manhattan

$5,894

Philadelphia

$133,887

San Francisco

$117,726

$4,440

Newark, N.J.

$108,506

$3,977

Los Angeles

$102,589

$3,430

New York City

$3,303 0

Annual Cost (dollars)

$1000

$2000

$3000

$4000

$5000

$6000

Source: Runzheimer International

Source: Runzheimer

63. Temperature Line Graph The table below gives the low temperature for each day of one week in White Bear Lake, Minnesota. Use the diagram in the figure to draw a line graph of the information in the table. 10°

Day Monday Tuesday Wednesday Thursday Friday Saturday Sunday

Temperature 10 8 5 3 8 5 7

F F F F F F F



Temperature (Fahrenheit)

LOW TEMPERATURES IN WHITE BEAR LAKE, MINNESOTA

6° 4° 2° 0° -2° -4° -6° -8° -10°

Mon

Tue

Wed

Thu

Fri

Sat

Sun

64. Temperature Line Graph The table below gives the low temperature for each day of one week in Fairbanks, Alaska. Use the diagram in the figure to draw a line graph of the information in the table. 30°

LOW TEMPERATURES IN FAIRBANKS, ALASKA Temperature 26 5 9 12 3 15 20

F F F F F F F

Temperature (Fahrenheit)

Day Monday Tuesday Wednesday Thursday Friday Saturday Sunday

25° 20° 15° 10° 5° 0° -5° -10° -15° -20° -25° -30°

Mon

Tue

Wed

Thu

Fri

Sat

Sun

502

Chapter 7 Introduction to Algebra

Getting Ready for the Next Section The problems below review some of the properties of addition and multiplication we covered in Chapter 1. Rewrite each expression using the commutative property of addition or multiplication.

65. 3  x

66. 4y

Rewrite each expression using the associative property of addition or multiplication.

67. 5  (7  a)

68. (x  4)  6

69. 3(4y)

70. (3y)8

Apply the distributive property to each expression.

71. 5(3  7)

72. 8(4  2)

Simplify.

73. 62

74. 122

75. 43

76. 52

77. 2(100)  2(75)

78. 2(100)  2(53)

79. 100(75)

80. 100(53)

Maintaining Your Skills The problems below review addition, subtraction, multiplication, and division of positive and negative numbers, as covered in this chapter. Perform the indicated operations.

81. 8  (4)

82. 8  4

83. 8  (4)

84. 8  4

85. 8  (4)

86. 8  (4)

87. 8(4)

88. 8(4)

89. 8(4)

90. 8  (4)

91. 8  4

92. 8  (4)

Extending the Concepts Find the next term in each sequence below.

93. 32, 16, 8, . . .

94. 243, 81, 27, . . .

95. 32, 16, 8, . . .

96. 243, 81, 27, . . .

Simplify each of the following expressions. 6  3(2  11) 6  3(2  11)

97. 

8  4(3  5) 8  4(3  5)

98. 

6  (3  4)  3 123

99. 

7  (3  6)  4 1  2  3

100. 

Simplifying Algebraic Expressions

7.6 Objectives A Simplify expressions by using the

Introduction . . .

associative property.

The woodcut shown here depicts Queen Dido of Carthage around 900 B.C., having

B

Apply the distributive property to expressions containing numbers and variables.

C

Use the distributive property to combine similar terms.

D

Use the formulas for area and perimeter of squares and rectangles.

an ox hide cut into small strips that will be tied together to make a long rope. The rope will be used to enclose her territory. The question, which has become known as the Queen Dido problem, is: what shape will enclose the largest territory? To translate the problem into something we are more familiar with, suppose we have 24 yards of fencing that we are to use to build a rectangular dog run. If we want the dog run to have the largest area possible then we want the rectangle, with perimeter 24 yards, that encloses the largest area. The diagram below shows six dog runs, each of which has a

Examples now playing at

MathTV.com/books

perimeter of 24 yards. Notice how the length decreases as the width increases.

Dog Runs with Perimeter  24 yards

11

1

10

2

9

3

8

7

4

6

5

6

Since area is length times width, we can build a table and a line graph that show how the area changes as we change the width of the dog run.

Area Enclosed by Fixed Perimeter

AREA ENCLOSED BY RECTANGLE OF PERIMETER 24 YARDS Area (Square Yards)

1

11

2

20

3

27

4

32

5

35

6

36

36

Area (square yards)

Width (Yards)

40

32 28 24 20 16 12 8 4 0

1

2

3

4

5

6

7

Width (yards)

7.6 Simplifying Algebraic Expressions

503

504

Note

Chapter 7 Introduction to Algebra In this section we want to simplify expressions containing variables—that is,

An algebraic expression does not contain an equal sign

algebraic expressions. An algebraic expression is a combination of constants and variables joined by arithmetic operations such as addition, subtraction, multiplication and division.

A Using the Associative Property To begin let’s review how we use the associative properties for addition and multiplication to simplify expressions. Consider the expression 4(5x). We can apply the associative property of multiplication to this expression to change the grouping so that the 4 and the 5 are grouped together, instead of the 5 and the x. Here’s how it looks: 4(5x)  (4 5)x  20x

Associative property Multiplication: 4  5  20

We have simplified the expression to 20x, which in most cases in algebra will be easier to work with than the original expression.

PRACTICE PROBLEMS Multiply. 1. 5(7a)

Here are some more examples.

EXAMPLE 1

7(3a)  (7  3)a  21a

2. 3(9x)

EXAMPLE 2

Associative property 7 times 3 is 21

2(5x)  (2  5)x  10x

3. 5(8y)

EXAMPLE 3

3(4y)  [3(4)] y  12y

Associative property The product of 2 and 5 is 10

Associative property 3 times 4 is 12

We can use the associative property of addition to simplify expressions also. Simplify. 4. 6  (9  x)

EXAMPLE 4

3  (8  x)  (3  8)  x  11  x

5. (3x  7)  4

EXAMPLE 5

Associative property The sum of 3 and 8 is 11

(2x  5)  10  2x  (5  10)  2x  15

Associative property Addition

B Using the Distributive Property In Chapter 1 we introduced the distributive property. In symbols it looks like this: a(b  c)  ab  ac Because subtraction is defined as addition of the opposite, the distributive property holds for subtraction as well as addition. That is, a(b  c)  ab  ac Apply the distributive property.

We say that multiplication distributes over addition and subtraction. Here are

6. 6(x  4)

some examples that review how the distributive property is applied to expres-

Answers 1. 35a 2. 27x 3. 40y 4. 15  x 5. 3x  11 6. 6x  24

sions that contain variables.

EXAMPLE 6

4(x  5)  4(x)  4(5)  4x  20

Distributive property Multiplication

505

7.6 Simplifying Algebraic Expressions

EXAMPLE 7

2(a  3)  2(a)  2(3)  2a  6

7. 7(a  5)

Distributive property Multiplication

In Examples 1–3 we simplified expressions such as 4(5x) by using the associative property. Here are some examples that use a combination of the associative property and the distributive property.

EXAMPLE 8

Distributive property Associative property Multiplication

8. 6(4x  5)

Distributive property Associative property and multiplication

9. 3(8a  4)

4(5x  3)  4(5x)  4(3)  (4  5)x  4(3)  20x  12

EXAMPLE 9

7(3a  6)  7(3a)  7(6)  21a  42

EXAMPLE 10

5(2x  3y)  5(2x)  5(3y)  10x  15y

Distributive property Associative property and multiplication

10. 8(3x  4y)

We can also use the distributive property to simplify expressions like 4x  3x. Because multiplication is a commutative operation, we can also rewrite the distributive property like this: b  a  c  a  (b  c)a Applying the distributive property in this form to the expression 4x  3x, we have 4x  3x  (4  3)x  7x

Distributive property Addition

C Similar Terms Expressions like 4x and 3x are called similar terms because the variable parts are the same. Some other examples of similar terms are 5y and 6y and the terms 7a, 13a, and

3  a. 4

To simplify an algebraic expression (an expression that involves

both numbers and variables), we combine similar terms by applying the distributive property. Table 1 shows several pairs of similar terms and how they can be combined using the distributive property.

TABLE 1

Original Expression 4x  3x 7a  a 5x  7x 8y  y 4a  2a 3x  7x

Apply Distributive Property      

(4  3)x (7  1)a (5  7)x (8  1)y (4  2)a (3  7)x

Simplified Expression      

7x 8a 2x 7y 6a 4x

As you can see from the table, the distributive property can be applied to any combination of positive and negative terms so long as they are similar terms.

Answers 7. 7a  35 8. 24x  30 9. 24a  12 10. 24x  32y

506

Chapter 7 Introduction to Algebra

D Algebraic Expressions Representing Area and Perimeter Below are a square with a side of length s and a rectangle with a length of l and a width of w. The table that follows the figures gives the formulas for the area and perimeter of each.

Square

Rectangle

w

s

l

Area A Perimeter P

11. Find the area and perimeter of a square if its side is 12 feet long.

EXAMPLE 11

Square

Rectangle

s2 4s

lw 2l  2w

Find the area and perimeter of a square with a side 6

inches long.

SOLUTION

Substituting 6 for s in the formulas for area and perimeter of a

square, we have Area  A  s2  62  36 square inches Perimeter  P  4s  4(6)  24 inches

12. A football field is 100 yards long and approximately 53 yards wide. Find the area and perimeter.

EXAMPLE 12

A soccer field is 100 yards long and 75 yards wide. Find

the area and perimeter. 100 yd

75 yd

SOLUTION

Substituting 100 for l and 75 for w in the formulas for area and

perimeter of a rectangle, we have Area  A  l w  100(75)  7,500 square yards Perimeter  P  2l  2w  2(100)  2(75)  200  150  350 yards

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Without actually multiplying, how do you apply the associative property to the expression 4(5x)? 2. What are similar terms? 3. Explain why 2a  a is a, rather than 1. Answers 11. A  144 sq ft, P  48 ft 12. A  5,300 sq yd, P  306 yd

4. Can two rectangles with the same perimeter have different areas? Explain your answer.

7.6 Problem Set

Problem Set 7.6 A Apply the associative property to each expression, and then simplify the result. [Examples 1–5] 1. 5(4a)

2. 8(9a)

3. 6(8a)

4. 3(2a)

5. 6(3x)

6. 2(7x)

7. 3(9x)

8. 4(6x)

9. 5(2y)

10. 3(8y)

11. 6(10y)

12. 5(5y)

13. 2  (3  x)

14. 9  (6  x)

15. 5  (8  x)

16. 3  (9  x)

17. 4  (6  y)

18. 2  (8  y)

19. 7  (1  y)

20. 4  (1  y)

21. (5x  2)  4

22. (8x  3)  10

23. (6y  4)  3

24. (3y  7)  8

25. (12a  2)  19

26. (6a  3)  14

27. (7x  8)  20

28. (14x  3)  15

B Apply the distributive property to each expression, and then simplify. [Examples 6–10] 29. 7(x  5)

30. 8(x  3)

31. 6(a  7)

32. 4(a  9)

33. 2(x  y)

34. 5(x  a)

35. 4(5  x)

36. 8(3  x)

37. 3(2x  5)

38. 8(5x  4)

39. 6(3a  1)

40. 4(8a  3)

41. 2(6x  3y)

42. 7(5x  y)

43. 5(7  4y)

44. 8(6  3y)

C Use the distributive property to combine similar terms. (See Table 1.) 45. 3x  5x

46. 7x  8x

47. 3a  a

48. 8a  a

49. 2x  6x

50. 3x  9x

51. 6y  y

52. 3y  y

53. 8a  2a

54. 7a  5a

55. 4x  9x

56. 5x  11x

507

508

Chapter 7 Introduction to Algebra

Applying the Concepts 57. A farmer is replacing several turbines on his windmills. He plans to replace x turbines, and he is going to get $300 off each turbine he buys. Also, he’ll get a $250 rebate on his entire purchase. Write an expression that describes this situation and then simplify.

Solar Versus Wind Energy Costs Equipment Co

st:

Equipment Co

$620 0 Modules $1570 Fi xed Rack ller $971 Charge Cont ro $4 40 Cable $9181 TOTA L

st: $330 0 $300 0 $715

Tu rbine Tower Cable

$7015

TOTA L

58. A homeowner is replacing 4 solar modules. She is going to reSource: a Limited 2006

ceive a discount of some amount x off each module and a $350 mail-in rebate. Write an expression that describes this situation and then simplify.

D Area and Perimeter Find the area and perimeter of each square if the length of each side is as given below. [Example 11] 59. s  6 feet

60. s  14 yards

61. s  9 inches

62. s  15 meters

D Area and Perimeter Find the area and perimeter for a rectangle if the length and width are as given below. [Example 12] 63. l  20 inches, w  10 inches

64. l  40 yards, w  20 yards

65. l  25 feet, w  12 feet

66. l  210 meters, w  120 meters

Temperature Scales In the metric system, the scale we use to measure temperature is the Celsius scale. On this scale water boils at 100 degrees and freezes at 0 degrees. When we write 100 degrees measured on the Celsius scale, we use the notation 100°C, which is read “100 degrees Celsius.” If we know the temperature in degrees Fahrenheit, we can convert to degrees Celsius by using the formula 5(F  32) C   9 where F is the temperature in degrees Fahrenheit. Use this formula to find the temperature in degrees Celsius for each of the following Fahrenheit temperatures.

67. 68°F

68. 59°F

69. 41°F

70. 23°F

71. 14°F

72. 32°F

Chapter 7 Summary Absolute Value [7.1] EXAMPLES The absolute value of a number is its distance from 0 on the number line. It is the

1. 3  3 and 3  3

numerical part of a number. The absolute value of a number is never negative.

Opposites [7.1] Two numbers are called opposites if they are the same distance from 0 on the

2. (5)  5 and (5)  5

number line but in opposite directions from 0. The opposite of a positive number is a negative number, and the opposite of a negative number is a positive number.

Addition of Positive and Negative Numbers [7.2] 1. To add two numbers with the same sign: Simply add absolute values and use

3.

the common sign. If both numbers are positive, the answer is positive. If both

358 3  (5)  8

numbers are negative, the answer is negative. 5  (3)  2 5  3  2

2. To add two numbers with different signs: Subtract the smaller absolute value from the larger absolute value. The answer has the same sign as the number with the larger absolute value.

Subtraction [7.3] Subtracting a number is equivalent to adding its opposite. If a and b represent

4.

3  5  3  (5)  2 3  5  3  (5)  8 3  (5)  3  5  8 3  (5)  3  5  2

5.

3(5)  15 3(5)  15 3(5)  15 3(5)  15

numbers, then subtraction is defined in terms of addition as follows: a  b  a  (b) h h

Subtraction

Addition of the opposite

Multiplication with Positive and Negative Numbers [7.4] To multiply two numbers, multiply their absolute values.

1. The answer is positive if both numbers have the same sign. 2. The answer is negative if the numbers have different signs.

Division [7.5] 6. The rule for assigning the correct sign to the answer in a division problem is the same as the rule for multiplication. That is, like signs give a positive answer, and

12  3 4 12   3 4 12   3 4

unlike signs give a negative answer.

12  3 4

Chapter 7

Summary

509

510

Chapter 7 Introduction to Algebra

Simplifying Expressions [7.6] 7. Simplify. a. 2(5x)  (2  5)x  10x b. 4(2a  8)  4(2a)  4(8)

We simplify algebraic expressions by applying the commutative, associative, and distributive properties.

 8a  32

Combining Similar Terms [7.6] 8. Combine similar terms. a. 5x  7x  (5  7)x  12x b. 2y  8y  (2  8)y  6y

We combine similar terms by applying the distributive property.

Chapter 7

Review

Give the opposite of each number. [7.1]

1. 17

2. 32

3 5

3. 4.6

4. 

7. 3 ; 2

8. 4 ; 6

For each pair of numbers, name the smaller number. [7.1]

5. 6; 6

6. 8; 3

Simplify each expression. [7.1]

9. (4)

10.  4

11. 6

12. 19

Perform the indicated operations. [7.2, 7.3, 7.4, 7.5]

13. 5  (7)

14. 3  8

15. 345  (626)

16. 23  58

17. 7  9  4  6

18. 7  5  2  3

19. 4  (3)

20. 30  42

21. 5(4)

22. 4(3)

23. (56)(31)

24. (20)(4)

48 16

25. 

14 7

20 5

26. 

27. 

25 5

28. 

Simplify the following expressions as much as possible. [7.2, 7.3, 7.4, 7.5]

 4 3

2

29. (6)2

30. 

33. 7  4(6  9)

34. (3)(4)  2(5)

84 8  4

37. 

4  2(5) 64

38. 

31. (2)3

32. (0.2)4

35. (7  3)(7  9)

36. 3(6)  8(2  5)

8(2)  5(4) 12  3

39. 

2(5)  4(3) 10  8

40. 

Chapter 7

Review

511

512

Chapter 7 Introduction to Algebra

41. Give the sum of 19 and 23. [7.2]

42. Give the sum of 78 and 51. [7.2]

43. Find the difference of 6 and 5. [7.3]

44. Subtract 8 from 10. [7.3]

45. What is the product of 9 and 3? [7.4]

46. What is 3 times the sum of 9 and 4? [7.2, 7.4]

47. Divide the product of 8 and 4 by 16. [7.4, 7.5]

48. Give the quotient of 38 and 2. [7.5]

Indicate whether each statement is True or False. [7.2, 7.3, 7.4, 7.5] 10 5

49.   2

50. 10  (5)  15

51. 2(3)  3  (3)

52. 6  (2)  8

53. 3  5  5  3

54. Reaction Distance The table below shows how many feet your car will travel from the time you decide you want to stop to the time it takes you to hit the brake pedal. Use the template to construct a line graph of the information in the table. [7.1] 100 90

REACTION DISTANCES Distance (ft)

0 10 20 30 40 50 60 70 80

0 11 22 33 44 55 66 77 88

Distance (ft)

Speed (mi/hr)

80 70 60 50 40 30 20 10 0

10

20

30

40

50

60

70

80

90

Speed (mph)

55. Gambling A gambler wins $58 Saturday night and then

56. Name two numbers that are 7 units from 8 on the

loses $86 on Sunday. Use positive and negative num-

number line. [7.1]

bers to describe this situation. Then give the gambler’s net loss or gain as a positive or negative number. [7.2]

57. Temperature On Wednesday, the temperature reaches a

58. If the difference between two numbers is 3, and one

high of 17° above 0 and a low of 7° below 0. What is

of the numbers is 5, what is the other number? [7.3]

the difference between the high and low temperatures for Wednesday? [7.3]

Use the associative properties to simplify each expression. [7.6]

59. (3x  4)  8

60. 8(3x)

61. 3(7a)

62. 6(5y)

Apply the distributive property and then simplify if possible. [7.6]

63. 4(x  3)

64. 2(x  5)

65. 7(3y  8)

66. 3(2a  5b)

68. 8a  10a

69. 5y  y

70. 12x  4x

Combine similar terms. [7.6]

67. 7x  4x

Chapter 7

Cumulative Review

Simplify.

1.   

2.   

5 6

3. 613  297

2

6. 53(807)

7.   (10)

3 5

5.

2 7

7 6

 3 

4



1 2

1 3

4. 3   

1

2

4 6  3 

5 8

7 8

9. Change 4  to an improper fraction.

8. Round 37.6451 to the nearest hundredth.

10. Write the number 38,609 in words.

11. Identify the property or properties used in the following: 5(x  9)  5(x)  5(9)

Simplify:

12. 6(3)3  9(2)2

13.

  49 36

3 8

1 4

2 3

3 4

5 6

14.     

15. (0.2)3  (0.3)2

17. (6)

95 9  5

16. 

Write each ratio as a fraction in lowest terms.

19.  to 

18. 24 seconds to 1 minute

7 8

49 6

21. Write 4  as a decimal.

22. Change  to a percent.

3 8

23. Change 76% to a fraction.

24. What is 2.5% of 40?

25. 17 is what percent of 42.5?

20. Change  to a mixed number.

Make the following conversions.

26. 350 m to kilometers

27. 14 gal to liters

29. 10 is 50% of what number?

30. Reduce .

14 25

28. Write  as a decimal.

99 36

Chapter 7

Cumulative Review

513

514

Chapter 7 Introduction to Algebra

31. Temperature On Thursday, Arturo notices that the tem-

32. Sale Price A dress that normally sells for $129 is on sale

perature reaches a high of 9° above 0 and a low of 8°

for 20% off the normal price. What is the sale price of

below 0. What is the difference between the high and

the dress?

low temperatures for Thursday?

33. Ratio If the ratio of men to women in a self-defense

34. Surfboard Length A surfing company decides that a surf-

class is 3 to 4, and there are 15 men in the class, how

board would be more efficient if its length were re-

many women are in the class?

duced by 38 inches. If the original length was 7 feet

5

3  16

inches, what will be the new length of the board (in

inches)?

35. Average Distance A bicyclist on a cross-country trip travels 72 miles the first day, 113 miles the second day, 108

36. Area and Perimeter Find the area and perimeter of the triangle below.

miles the third day, and 95 miles the fourth day. What is her average distance traveled during the four days? 5

9 6 ft

1

6 ft

7 3 ft

11 ft

37. Cost of Chocolate If white chocolate sells for $4.32 per

38. Number Line The distance between two numbers on the

pound, how much will 2.5 pounds cost?

number line is 9. If one of the numbers is 4, what are the two possibilities for the other number?

39. Basketball Shots Erica makes a total of 8 two-point baskets in her first 18 games of the season. If she continues at the same rate, how many two-point baskets will she make in 45 games?

40. Stopping Distances The bar chart below shows how many feet it takes to stop a car traveling at different rates of speed, once the brakes are applied. Use this information in the bar chart to fill in the table. 400 352

Stopping distance (ft)

350 300

269

250

Speed (mi/hr)

Distance (ft)

20

22

30 198

200

40 137

150

50

88

100 49

50 0

198

22

269

20

30

40

50

60

Speed (mi/hr)

70

80 80

Chapter 7

Test

Give the opposite of each number. 2 3

2. 

1. 14

Place an inequality symbol ( or ) between each pair of numbers so that the resulting statement is true.

3. 1

4

4. 4

2

Simplify each expression.

5. (7)

6.  2

Perform the indicated operations.

7. 8  (17)

11. (6)(7)

8. 4.2  1.7

1 3

12. (18)

2 3

4

 5

9.   

80 16

10. 65  (29)

3.5 0.7

13. 

14. 

17. (7)(3)  (2)(5)

18. (8  5)(6  11)

Simplify the following expressions as much as possible.

15. (3)2

5  3(3) 57

19. 

16. (2)3

3(2)  5(2) 73

20. 

21. Give the sum of 15 and 46.

22. Subtract 5 from 12.

23. What is the product of 8 and 3?

24. Give the quotient of 45 and 9.

Chapter 7

Test

515

516

Chapter 7 Introduction to Algebra

25. Garbage Production The table and bar chart below give the annual production of garbage in the United States for some specific years.

The Growing Garbage Problem Garbage (Millions of Tons)

1960

88

1970

121

1980

152

1990

205

2000

217

Garbage (millions of tons)

Year

250 205

215

200 152

150 121 88

100 50 0

1960

1970

1980

1990

2000

Use the information from the table and bar chart to construct a line graph using the template below.

Garbage (millions of tons)

250 200 150 100 50 0 1960

1970

1980

1990

2000

26. Gambling A gambler loses $100 Saturday night and

27. Temperature On Friday, the temperature reaches a high

wins $65 on Sunday. Give the gambler’s net loss or

of 21° above 0 and a low of 4° below 0. What is the dif-

gain as a positive or negative number.

ference between the high and low temperatures for Friday?

Apply the distributive property and simplify.

28. 7(x  5)

29. 4(5x  1)

30. 2(9x  8y)

Combine similar terms.

31. 12x  20x

32. 9a  a

Chapter 7 Projects INTRODUCTION TO ALGEBRA

GROUP PROJECT Random Motion Number of People Time Needed Equipment Background

3 15 minutes

Stage

Coin

Die

Position of Ant

0





0

Coins, dice, pencil, and paper 1

Microscopic atoms and molecules move randomly. We use random movement models to

2

help us understand their motion. Random mo-

3

tion also helps us understand things like the stock market and computer science.

4

In a random walk, an ant starts at a lamppost

5

and takes steps of equal length along the street.

6

We can think of the lamppost as the origin. The ant either takes a step in the negative or posi-

7

tive direction. Mathematicians have studied

8

questions such as where the ant is likely to end up after taking a certain number of steps.

9 10

Procedure

You will use a coin and die to simulate random motion. The ant will start at 0 on the number line. Roll the die and flip the coin. The ant will move the number of steps shown on the die. If the coin comes up heads, the ant moves in the positive direction. If the coin comes up tails, the ant moves in the negative direction. Repeat this process 10 times. Start each stage from the ending position of the previous stage. For example, if the ant ends up at 3 after Stage 1, then in Stage 2 the ant starts at 3. Record your results in the table.

Chapter 7

Projects

517

RESEARCH PROJECT David Harold Blackwell At age 22, David Blackwell earned his doctorate, becoming the seventh African American to earn a Ph.D. in mathematics. In high school, Blackwell

did

not

care

for

algebra

and

trigonometry. When he took a course in analythough Blackwell faced a good deal of racism during his career, he became a successful teacher, author, and mathematician. Research the life and work of Dr. Blackwell, and then present your results in an essay.

518

Chapter 7 Introduction to Algebra

Courtesy of David Harold Blackwell

sis, he really became interested in math. Al-

8

Solving Equations

Chapter Outline 8.1 The Distributive Property and Algebraic Expressions 8.2 The Addition Property of Equality 8.3 The Multiplication Property of Equality 8.4 Linear Equations in One Variable 8.5 Applications 8.6 Evaluating Formulas

Introduction Central Park in New York City was the first landscaped public park in the United 1

States. More than 25 million people visit the park each year. Central Park is 2 mile wide and covers an area of 1.4 square miles. A person who jogs around the perimeter of the park will cover approximately 6.6 miles. Because the park can be modeled with a rectangle, we can use these numbers to find the length of the park. In fact, solving either of the two equations below will give us the length. 1  x  1.4 2

1 2x  2    6.6 2

In this chapter, we will learn how to take the numbers and relationships given in the paragraph above and translate them into equations like the ones above. Before we do that, we will learn how to solve these equations, and many others as well.

Comparing Parks

Central Park (New York) Stanley Park (Vancouver) Richmond Park (London) Griffith Park (Los Angeles)

843 acres 1,000 acres 2,360 acres 4,210 acres

The illustration here shows the area of Central Park compared to other prominent parks in large cities.

519

Chapter Pretest The pretest below contains problems that are representative of the problems you will find in the chapter. Simplify.

1. 4a  1  5a  8

2. 2(5y  6)  4y

Solve each equation. 1 5

3. a  4  2

4. 5y  9  4y  7  11

5.  x  3

6. 2x  9  11

7. 2a  1  5(a  2)  1

8.     5

9. Find the value of 3x  4 when x  2. 11. The sum of a number and 6 is 17. Find the number.

x 3

x 4

10. Is x  5 a solution to the equation 6x  28  1? 12. If four times a number is decreased by 7, the result is 25. Find the number.

14. Graph y  3x  1.

13. Plot the following points: (3, 1), (3, 0), (2, 1), (2, 2).

y

y

5 4 3 2 1

5 4 3 2 1 −5−4−3−2−1 −1 −2 −3 −4 −5

1 2 3 4 5

−5−4−3−2−1 −1 −2 −3 −4 −5

x

1 2 3 4 5

x

Getting Ready for Chapter 8 The problems below review material covered previously that you need to know in order to be successful in Chapter 8. If you have any difficulty with the problems here, you need to go back and review before going on to Chapter 8. Simplify.

1. 2  7

2. 180  45

5. (4)(5)

6. 



5 4

9.  

6 3

8

  15 

13. 3x  7x

5 8

3 2

5 4



7.  (12)

8.   5 9

1 3

4

 5 

10. 4(1)  9

11.  (15)  2

12.  (95  32)

14. 4(3x)

15. 4(x  5)

16. 2  x

17. Write in symbols: the sum of x and 2.

1

2 

18. Find the perimeter.

x 3x

520

3 4

4.   

3. 2  (4)

Chapter 8 Solving Equations

The Distributive Property and Algebraic Expressions We recall that the distributive property from Section 1.5 can be used to find the area of a rectangle using two different methods.

4

x3

3

Area  4(x )  4(3)

Objectives A Apply the distributive property to an expression.

4

x

8.1 B C

Combine similar terms.

D

Solve applications involving complementary and supplementary angles.

Find the value of an algebraic expression.

Area  4(x  3)

 4x  12

 4x  12

Since the areas are equal, the equation 4(x  3)  4(x )  4(3) is a true statement.

Examples now playing at

MathTV.com/books

A The Distributive Property PRACTICE PROBLEMS

EXAMPLE 1

Apply the distributive property to the expression:

to the expression 6(x  4).

5(x  3)

SOLUTION

1. Apply the distributive property

Distributing the 5 over x and 3, we have

5(x  3)  5(x)  5(3)

Distributive property Multiplication

 5x  15 Remember, 5x means “5 times x.”

The distributive property can be applied to more complicated expressions involving negative numbers.

EXAMPLE 2 SOLUTION

2. Multiply: 3(2x  4)

Multiply: 4(3x  5)

Multiplying both the 3x and the 5 by 4, we have 4(3x  5)  4(3x)  (4)5  12x  (20)  12x  20

Distributive property Multiplication Definition of subtraction

Notice, first of all, that when we apply the distributive property here, we multiply through by 4. It is important to include the sign with the number when we use the distributive property. Second, when we multiply 4 and 3x, the result is 12x because 4(3x)  (4  3)x  12x

Associative property Multiplication

Answers 1. 6x  24 2. 6x  12

8.1 The Distributive Property and Algebraic Expressions

521

522

Chapter 8 Solving Equations

1 3. Multiply:  (2x  4)

EXAMPLE 3

2

SOLUTION

1 Multiply:  (3x  12) 3

1 1 1  (3x  12)   (3x)   (12) 3 3 3

Distributive property

12  1x   3

Simplify

x4

Divide

We can also use the distributive property to simplify expressions like 4x  3x. Because multiplication is a commutative operation, we can rewrite the distributive property like this: b  a  c  a  (b  c)a Applying the distributive property in this form to the expression 4x  3x, we have: 4x  3x  (4  3)x  7x

Distributive property Addition

B Similar Terms

Note

We are using the word term in a different sense here than we did with fractions. (The terms of a fraction are the numerator and the denominator.)

Recall that expressions like 4x and 3x are called similar terms because the variable parts are the same. Some other examples of similar terms are 5y and 6y, and the terms 7a, 13a,

3 a. 4

To simplify an algebraic expression (an expression

that involves both numbers and variables), we combine similar terms by applying the distributive property. Table 1 reviews how we combine similar terms using the distributive property. TABLE 1

Original Expression 4x  3x 7a  a 5x  7x 8y  y 4a  2a 3x  7x

Apply Distribution Property      

(4  3)x (7  1)a (5  7)x (8  1)y (4  2)a (3  7)x

Simplified Expression      

7x 8a 2x 7y 6a 4x

As you can see from the table, the distributive property can be applied to any combination of positive and negative terms so long as they are similar terms. 4. Simplify: 6x  2  3x  8

EXAMPLE 4 SOLUTION

Simplify: 5x  2  3x  7

We begin by changing subtraction to addition of the opposite and

applying the commutative property to rearrange the order of the terms. We want similar terms to be written next to each other. 5x  2  3x  7  5x  3x  (2)  7  (5  3)x  (2)  7  8x  5

Commutative property Distributive property Addition

Notice that we take the negative sign in front of the 2 with the 2 when we rearrange terms. How do we justify doing this? Answers 3. x  2 4. 9x  6

523

8.1 The Distributive Property and Algebraic Expressions

EXAMPLE 5 SOLUTION

5. Simplify: 2(4x  3)  7

Simplify: 3(4x  5)  6

We begin by distributing the 3 across the sum of 4x and 5. Then we

combine similar terms. 3(4x  5)  6  12x  15  6

Distributive property Add 15 and 6

 12x  21

EXAMPLE 6 SOLUTION

Simplify: 2(3x  1)  4(2x  5)

6. Simplify: 3(2x  1)  5(4x  3)

Again, we apply the distributive property first; then we combine

similar terms. Here is the solution showing only the essential steps: 2(3x  1)  4(2x  5)  6x  2  8x  20

Distributive property Combine similar terms

 14x  18

C The Value of an Algebraic Expression An expression such as 3x  5 will take on different values depending on what x is. If we were to let x equal 2, the expression 3x  5 would become 11. On the other hand, if x is 10, the same expression has a value of 35: When

x2

When

the expression

3x  5

the expression

3x  5

becomes

3(2)  5

becomes

3(10)  5

EXAMPLES

x  10

65

 30  5

 11

 35

Find the value of each of the following expressions by re-

placing the variable with the given number. Original Expression

Value of the Variable

7.

3x  1

x2

8.

2x  3  4x

x  1

9.

y2  6y  9

y4

Value of the Expression 7. Find the value of 4x  7 when

3(2)  1  6  1  5

x  3.

2(1)  3  4(1)  2  3  (4)  9

8. Find the value of 2x  5  6x when x  2.

42  6(4)  9  16  24  9  1

9. Find the value of y2  10y  25 when y  2.

EXAMPLE 10

Find the area of a 30-W solar panel

10. Find the area of a 30-W solar

shown here with a length of 15 inches and a width of

panel with a length of 25 cm and a width of 8  2x cm.

10  3x inches.

SOLUTION

15”

Previously we worked with area, so we

know that Area  (length) (width). Using the values for length and width, we have:

10 + 3x

A  lw A  15(10  3x)  150  45x

length  15; width  10  3x Distributive property

The area of this solar panel is 150 + 45x square inches.

Answers 5. 8x  13 6. 26x  12 7. 5 8. 21 9. 49 10. 200  50x cm2

524

Chapter 8 Solving Equations

FACTS FROM GEOMETRY Angles An angle is formed by two rays with the same endpoint. The common endpoint is called the vertex of the angle, and the rays are called the sides of the angle. In Figure 1, angle θ (theta) is formed by the two rays OA and OB. The vertex of θ is O. Angle θ is also denoted as angle AOB, where the letter associated with the vertex is always the middle letter in the three letters used to denote the angle. Degree Measure The angle formed by rotating a ray through one complete revolution about its endpoint (Figure 2) has a measure of 360 degrees, which we write as 360°.

B 

O

A

One complete revolution = 360

FIGURE 1

FIGURE 2

One degree of angle measure, written 1°, is

1  360

of a complete rotation of a ray

about its endpoint; there are 360° in one full rotation. (The number 360 was decided upon by early civilizations because it was believed that the Earth was at the center of the universe and the Sun would rotate once around the Earth every 360 days.) Similarly, 180° is half of a complete rotation, and 90° is a quarter of a full rotation. Angles that measure 90° are called right angles, and angles that measure 180° are called straight angles. If an angle measures between 0° and 90° it is called an acute angle, and an angle that measures between 90° and 180° is an obtuse angle. Figure 3 illustrates further.

90 180 Straight angle

Right angle

Acute angle

Obtuse angle

FIGURE 3

D

Complementary Angles and Supplementary Angles If two angles

add up to 90°, we call them complementary angles, and each is called the complement of the other. If two angles have a sum of 180°, we call them supplementary angles, and each is called the supplement of the other. Figure 4 illustrates the relationship between angles that are complementary and angles that are supplementary.







 Complementary angles:     90°

Supplementary angles:     180°

FIGURE 4

525

8.1 The Distributive Property and Algebraic Expressions

EXAMPLE 11

11. Find x in each of the following

Find x in each of the following diagrams.

a.

diagrams.

b.

a.

x 45°

x

x 30°

Complementary angles

SOLUTION

45°

Supplementary angles

Complementary angles

We use subtraction to find each angle.

b.

a. Because the two angles are complementary, we can find x by subtracting 30° from 90°:

x

x  90°  30°  60°

60°

We say 30° and 60° are complementary angles. The complement of 30° is 60°.

Supplementary angles

b. The two angles in the diagram are supplementary. To find x, we subtract 45° from 180°: x  180°  45°  135° We say 45° and 135° are supplementary angles. The supplement of 45° is 135°.

USING

TECHNOLOGY

Protractors When we think of technology, we think of computers and calculators. However, some simpler devices are also in the category of technology, because they help us do things that would be difficult to do without them. The protractor below can be used to draw and measure angles. In the diagram below, the protractor is being used to measure an angle of 120°. It can also be used

80 90 100 70 100 90 80 110 1 70 2 60 0 110 60 0 1 2 3 50 0 1 50 0 13

0

1

2

3

4

0 10 180 170 1 20 60

120°

170 180 0 160 0 20 10 15 0 30 14 0 4

3 15 0 4 0 14 0 0

to draw angles of any size.

5

6

7

8

9

10

11

If you have a protractor, use it to draw the following angles: 30°, 45°, 60°, 120°, 135°, and 150°. Then imagine how you would draw these angles without a protractor.

Answer 11. a. 45° b. 120°

526

Chapter 8 Solving Equations

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. What is the distributive property? 2. What property allows 5(x  3) to be rewritten as 5x  5(3)? 3. What property allows 3x  4x to be rewritten as 7x? 4. True or false? The expression 3x means 3 multiplied by x.

8.1 Problem Set

527

Problem Set 8.1 A For review, use the distributive property to combine each of the following pairs of similar terms. [Examples 1–3] 1. 2x  8x

2. 3x  7x

3. 4y  5y

4. 3y  10y

5. 4a  a

6. 9a  a

7. 8(x  2)

8. 8(x  2)

9. 2(3a  7)

10. 5(3a  2)

1 3

11.  (3x  6)

1 2

12.  (2x  4)

B Simplify the following expressions by combining similar terms. In some cases the order of the terms must be rearranged first by using the commutative property. [Examples 4–6]

13. 4x  2x  3  8

14. 7x  5x  2  9

15. 7x  5x  6  4

16. 10x  7x  9  6

17. 2a  a  7  5

18. 8a  3a  12  1

19. 6y  2y  5  1

20. 4y  3y  7  2

21. 4x  2x  8x  4

22. 6x  5x  12x  6

23. 9x  x  5  1

24. 2x  x  3  8

25. 2a  4  3a  5

26. 9a  1  2a  6

27. 3x  2  4x  1

28. 7x  5  2x  6

29. 12y  3  5y

30. 8y  1  6y

31. 4a  3  5a  2a

32. 6a  4  2a  6a

528

Chapter 8 Solving Equations

Apply the distributive property to each expression and then simplify.

33. 2(3x  4)  8

34. 2(5x  1)  10

35. 5(2x  3)  4

36. 6(4x  2)  7

37. 8(2y  4)  3y

38. 2(5y  1)  2y

39. 6(4y  3)  6y

40. 5(2y  6)  4y

41. 2(x  3)  4(x  2)

42. 3(x  1)  2(x  5)

43. 3(2a  4)  7(3a  1)

44. 7(2a  2)  4(5a  1)

C Find the value of each of the following expressions when x  5. [Examples 7–9] 45. 2x  4

46. 3x  2

47. 7x  8

48. 8x  9

49. 4x  1

50. 3x  7

51. 8  3x

52. 7  2x

Find the value of each of the following expressions when a  2.

53. 2a  5

54. 3a  4

55. 7a  4

56. 9a  3

57. a  10

58. a  8

59. 4  3a

60. 6  5a

8.1 Problem Set

529

Find the value of each of the following expressions when x  3. You may substitute 3 for x in each expression the way it is written, or you may simplify each expression first and then substitute 3 for x.

61. 3x  5x  4

62. 6x  8x  7

63. 9x  x  3  7

64. 5x  3x  2  4

65. 4x  3  2x  5

66. 7x  6  2x  9

67. 3x  8  2x  3

68. 7x  2  4x  1

Find the value of each of 12x  3 for each of the following values of x. 1 6

69. 

1 2

70. 

1 3

71. 

1 4

72. 

3 2

74. 

2 3

75. 

3 4

76. 

73. 

5 6

Use the distributive property to write two equivalent expressions for the area of each figure.

77.

78.

6

x

7

4

x

5

Write an expression for the perimeter of each figure.

79.

80.

Square

3x  2

x1 Rectangle

81.

3x  1

82.

4x  1 Parallelogram

2x  1

2x  3

Triangle 5x  4

4x  1

530

D

Chapter 8 Solving Equations

Applying the Concepts

83. Buildings This Google

84. Geometry This Google

Earth image shows the

Earth image shows the

Leaning Tower of Pisa.

Pentagon. The interior an-

Most buildings stand at a

gles of a regular pentagon

right angle, but the tower

are all the same and sum

is sinking on one side. The

to 540°. Find the size of

angle of inclination is the

each angle.

angle between the vertical and the tower. If the angle between the tower and the ground is 85° what is the angle of inclination?

Find x in each figure and decide if the two angles are complementary or supplementary. [Example 11]

86.

85.

x 35°

x 35°

87.

88.

x

x 70°

89. Luke earns $12 per hour working as a math tutor. We

70°

90. Kelly earns $15 per hour working as a graphic designer.

can express the amount he earns each week for work-

We can express the amount she earns each week for

ing x hours with the expression 12x. Indicate with a yes

working x hours with the expression 15x. Indicate with a

or no, which of the following could be one of Luke’s

yes or no which of the following could be one of Kelly’s

paychecks. If you answer no, explain your answer.

paychecks. If you answer no, explain your answer.

a. $60 for working five hours

a. $75 for working five hours

b. $100 for working nine hours

b. $125 for working nine hours

c. $80 for working seven hours

c. $90 for working six hours

d. $168 for working 14 hours

d. $500 for working 35 hours

531

8.1 Problem Set

92. Perimeter of a Rectangle As you know, the expression

91. Temperature and Altitude On a certain day, the temperature on the ground is 72 degrees Fahrenheit, and the

2l  2w gives the perimeter of a rectangle with length l

temperature at an altitude of A feet above the ground is

and width w. The garden below has a width of 32 feet

found from the expression 72 

A . 300

1

Find the tempera-

and a length of 8 feet. What is the length of the fence

ture at the following altitudes.

that surrounds the garden?

a. 12,000 feet b. 15,000 feet c. 27,000 feet

3.5 ft A 72˚F

8 ft

93. Cost of Bottled Water A water bottling company charges

94. Cellular Phone Rates A cellular phone company charges

$7 per month for their water dispenser and $2 for each

$35 per month plus 25 cents for each minute, or frac-

gallon of water delivered. If you have g gallons of water

tion of a minute, that you use one of their cellular

delivered in a month, then the expression 7  2g gives

 gives the amount of phones. The expression  100

the amount of your bill for that month. Find the

money, in dollars, you will pay for using one of their

monthly bill for each of the following deliveries.

phones for t minutes a month. Find the monthly bill for

a. 10 gallons

3500  25t

b. 20 gallons

using one of their phones:

a. 20 minutes in a month WBC

WATER BOTTLE CO.

b. 40 minutes in a month

Cell Phone Company Grover Beach, CA

MONTHLY BILL

August 2008

234 5th Street Glendora, CA 91740

DUE 07/23/08

Water dispenser

1

$7.00

Gallons of water

8

$2.00

DUE 08/15/08

Monthly Access per Phone: Charges: $0.25/minute

1

$35.00

50

$12.50 $47.50

$23.00

Getting Ready for the Next Section Add.

95. 4  (4)

100. 3  12

96. 2  (2)

5 8

3 4

101.   

97. 2  (4)

5 6

2 3

102.   

98. 2  (5)

3 4

3 4

103.    

99. 5  2

2 3

2 3

104.    

532

Chapter 8 Solving Equations

Simplify.

105. x  0

106. y  0

107. y  4  6

108. y  6  2

111. 6

112. 5

Maintaining Your Skills Give the opposite of each number.

109. 9

110. 12

Problems 113–118 review material we covered in Chapter 1. Match each statement on the left with the property that justifies it on the right.

113. 2(6  5)  2(6)  2(5)

a. b. c. d.

114. 3  (4  1)  (3  4)  1

Distributive property Associative property Commutative property Commutative and associative properties

115. x  5  5  x 116. (a  3)  2  a  (3  2) 117. (x  5)  1  1  (x  5) 118. (a  4)  2  (4  2)  a

Perform the indicated operation. 5 4

2 3

 15 

120.   

5

6

121. 12  

3 5

123.   

3 4

124.   

8

119.   

122. 6  

4 3

2 3

3 5

5 8

The Addition Property of Equality Introduction . . . Previously we defined complementary angles as two angles whose sum is 90°. If

8.2 Objectives A Identify a solution to an equation. B Use the addition property of equality to solve linear equations.

A and B are complementary angles, then A  B  90°

Examples now playing at

MathTV.com/books

A B Complementary angles If we know that A  30°, then we can substitute 30° for A in the formula above to obtain the equation 30°  B  90° In this section we will learn how to solve equations like this one that involve addition and subtraction with one variable. In general, solving an equation involves finding all replacements for the variable that make the equation a true statement.

A Solutions to Equations Definition A solution for an equation is a number that when used in place of the variable makes the equation a true statement.

For example, the equation x  3  7 has as its solution the number 4, because

Note

Although an equation may have many solutions, the equations we work with in the first part of this chapter will always have a single solution.

replacing x with 4 in the equation gives a true statement: When

x4

the equation

x37

becomes

437

or

77

EXAMPLE 1 SOLUTION

A true statement

PRACTICE PROBLEMS Is x  5 the solution to the equation 3x  2  17?

To see if it is, we replace x with 5 in the equation and find out if the

1. Show that x  3 is the solution to the equation 5x  4  11.

result is a true statement: When

x5

the equation

3x  2  17

becomes

3(5)  2  17 15  2  17 17  17

A true statement

Because the result is a true statement, we can conclude that x  5 is the solution

Answer 1. See solutions section.

to 3x  2  17.

8.2 The Addition Property of Equality

533

534

2. Is a  3 the solution to the equation 6a  3  2a  4?

Chapter 8 Solving Equations

EXAMPLE 2

Is a  2 the solution to the equation 7a  4  3a  2?

SOLUTION

a  2

When

7a  4  3a  2

the equation

7(2)  4  3(2)  2

becomes

14  4  6  2 10  8

A false statement

Because the result is a false statement, we must conclude that a  2 is not the solution to the equation 7a  4  3a  2.

B Addition Property of Equality We want to develop a process for solving equations with one variable. The most important property needed for solving the equations in this section is called the addition property of equality. The formal definition looks like this:

Addition Property of Equality Let A, B, and C represent algebraic expressions. AB

If then

ACBC

In words: Adding the same quantity to both sides of an equation never changes the solution to the equation.

This property is extremely useful in solving equations. Our goal in solving equations is to isolate the variable on one side of the equation. We want to end up with an equation of the form x  a number To do so we use the addition property of equality. Remember to follow this basic rule of algebra: Whatever is done to one side of an equation must be done to the other side in order to preserve the equality. 3. Solve for x: x  5  2

EXAMPLE 3 SOLUTION

Note

With some of the equations in this section, you will be able to see the solution just by looking at the equation. But it is important that you show all the steps used to solve the equations anyway. The equations you come across in the future will not be as easy to solve, so you should learn the steps involved very well.

Solve for x: x  4  2

We want to isolate x on one side of the equation. If we add 4 to

both sides, the left side will be x  4  (4), which is x  0 or just x. x  4  2 x  4  (4)  2  (4) x  0  6 x  6

Add 4 to both sides Addition x0x

The solution is 6. We can check it if we want to by replacing x with 6 in the original equation: When

x  6

the equation

x  4  2

becomes

6  4  2 2  2

Answers 2. No 3. 7

A true statement

535

8.2 The Addition Property of Equality

EXAMPLE 4

4. Solve for a: a  2  7

Solve for a: a  3  5 a35

SOLUTION

a3353 a08 a8

Add 3 to both sides Addition a0a

The solution to a  3  5 is a  8.

EXAMPLE 5 SOLUTION

5. Solve for y: y  6  2  8  9

Solve for y: y  4  6  7  1

Before we apply the addition property of equality, we must simplify

each side of the equation as much as possible: y4671 y26 y2262 y08 y8

EXAMPLE 6 SOLUTION

Simplify each side Add 2 to both sides Addition y0y 6. Solve for x: 5x  3  4x  4  7

Solve for x: 3x  2  2x  4  9

Simplifying each side as much as possible, we have 3x  2  2x  4  9 x  2  5 x  2  2  5  2 x  0  3 x  3

EXAMPLE 7 SOLUTION

3x  2x  x Add 2 to both sides Addition x0x 7. Solve for x: 5  7  x  2

Solve for x: 3  6  x  4

The variable appears on the right side of the equation in this prob-

lem. This makes no difference; we can isolate x on either side of the equation. We can leave it on the right side if we like: 3  6  x  4 9  x  4 9  (4)  x  4  (4) 13  x  0 13  x

Simplify the left side Add 4 to both sides Addition x0x

The statement 13  x is equivalent to the statement x  13. In either case the solution to our equation is 13.

EXAMPLE 8 SOLUTION

2 3

3 5 Solve: a     4 8 3 To isolate a we add 4 to each side:

5 6

8. Solve: a    

3 5 a    4 8 3 3 3 5 a        4 8 4 4 11 a  8 When solving equations we will leave answers like rather than change them to mixed numbers.

11  8

as improper fractions,

Answers 4. 9 5. 5 6. 0 7. 14 3 2

8. 

536

9. Solve: 5(3a  4)  14a  25

Chapter 8 Solving Equations

EXAMPLE 9 SOLUTION

Solve: 4(2a  3)  7a  2  5.

We must begin by applying the distributive property to separate

terms on the left side of the equation. Following that, we combine similar terms and then apply the addition property of equality. 4(2a  3)  7a  2  5 8a  12  7a  2  5 a  12  3 a  12  12  3  12 a9

Original equation Distributive property Simplify each side Add 12 to each side Addition

A Note on Subtraction Although the addition property of equality is stated for addition only, we can subtract the same number from both sides of an equation as well. Because subtraction is defined as addition of the opposite, subtracting the same quantity from both sides of an equation will not change the solution. If we were to solve the equation in Example 3 using subtraction instead of addition, the steps would look like this: x  4  2 x  4  4  2  4 x  6

Original equation Subtract 4 from each side Subtraction

In my experience teaching algebra, I find that students make fewer mistakes if they think in terms of addition rather than subtraction. So, you are probably better off if you continue to use the addition property just the way we have used it in the examples in this section. But, if you are curious as to whether you can subtract the same number from both sides of an equation, the answer is yes.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. An answer of true or false should be accompanied by a sentence explaining why the answer is true or false. 1. What is a solution to an equation? 2. True or false? According to the addition property of equality, adding the same value to both sides of an equation will never change the solution to the equation. 3. Show that x  5 is a solution to the equation 3x  2  17 without solving the equation. 4. True or false? The equations below have the same solution.

Answer 9. 45

Equation 1:

7x  5  19

Equation 2:

7x  5  3  19  3

8.2 Problem Set

537

Problem Set 8.2 A Check to see if the number to the right of each of the following equations is the solution to the equation. [Examples 1, 2] 1. 2x  1  5; 2

2. 4x  3  7; 1

3. 3x  4  19; 5

4. 3x  8  14; 2

5. 2x  4  2; 4

6. 5x  6  9; 3

7. 2x  1  3x  3; 2

8. 4x  5  2x  1; 6

9. x  4  2x  1; 4

10. x  8  3x  2; 5

B Solve each equation. [Examples 3, 4, 8] 11. x  2  8

12. x  3  5

13. x  4  7

14. x  6  2

15. a  9  6

16. a  3  1

17. x  5  4

18. x  8  3

19. y  3  6

20. y  5  1

21. a     

22. a     

25. y  7.3  2.7

26. y  8.2  2.8

3 5

4 5

23. x    

7 8

3 8

24. x    

1 3

2 3

1 4

3 4

538

Chapter 8 Solving Equations

B Simplify each side of the following equations before applying the addition property. [Examples 5–7] 27. x  4  7  3  10

28. x  6  2  5  12

29. x  6  4  3  2

30. x  8  2  7  1

31. 3  5  a  4

32. 2  6  a  1

33. 3a  7  2a  1

34. 5a  6  4a  4

35. 6a  2  5a  9  1

36. 7a  6  6a  3  1

37. 8  5  3x  2x  4

38. 10  6  8x  7x  6

B The following equations contain parentheses. Apply the distributive property to remove the parentheses, then simplify each side before using the addition property of equality. [Example 9]

39. 2(x  3)  x  4

40. 5(x  1)  4x  2

41. 3(x  4)  4x  3  7

42. 2(x  5)  3x  4  9

43. 5(2a  1)  9a  8  6

44. 4(2a  1)  7a  9  5

45. (x  3)  2x  1  6

46. (x  7)  2x  8  4

Find the value of x for each of the figures, given the perimeter.

47. P  36

48. P  30

x 10

10

5 12

x  12

50. P  60

49. P  16

26 5

5

10 x

x6

8.2 Problem Set

539

Applying the Concepts Temperature The chart shows the temperatures for some of the world’s hottest places. To convert from Celsius to Kelvin we use the formula

160

Heating Up

y  x  273, where y is the temperature in Kelvin and x is the tempera137˚F Al’Aziziyah, Libya

ture in Celsius. Use the formula to answer Questions 51 and 52.

140 120

134˚F Greenland Ranch, Death Valley, United States

51. The hottest temperature in Al’Aziziyah was 331 Kelvin. Convert

131˚F Ghudamis, Libya

this to Celsius.

131˚F Kebili, Tunisia

100 80

130˚F Tombouctou, Mali 60

52. The hottest temperature in Kebili, Tunisia, was 328 Kelvin. ConSource: Aneki.com

vert this to Celsius.

53. Geometry Two angles are complementary angles. If one

40

54. Geometry Two angles are supplementary angles. If

of the angles is 23°, then solving the equation

one of the angles is 23°, then solving the equation

x  23°  90° will give you the other angle. Solve the

x  23°  180° will give you the other angle. Solve the

equation.

equation.

A B Complementary angles

55. Theater Tickets The El Portal Center for the Arts in North

56. Geometry The sum of the angles in the triangle on the

Hollywood, California, holds a maximum of 400 people.

swing set is 180°. Use this fact to write an equation

The two balconies hold 86 and 89 people each; the rest

containing x. Then solve the equation.

of the seats are at the stage level. Solving the equation x  86  89  400 will give you the number of seats on the stage level.

a. Solve the equation for x. b. If tickets on the stage level are $30 each, and tickets in either balcony are $25 each, what is the maximum amount of money the theater can bring in for a show?

TICK ET

El Portal CENTER FOR THE ARTS Stage Seats Level

ET TICK

ny Balco Seats 2500

$

$30 00

x

67° 67°

540

Chapter 8 Solving Equations

Getting Ready for the Next Section Find the reciprocal of each number.

57. 4

1 2

59. 

58. 3

2 3

1 3

60. 

3 5

61. 

62. 

Multiply. 1 4

1 2

63. 2  

3 2

1 3

64.   4

2

3

67.  

5 3

1 4

65.   (3)

3

5



5 4

66.   (4)

4

 5 

68.  

69.  

72. 1  a

73. 4x  11  3x



4 3

70.  

3

 4 

Simplify.

71. 1  x

74. 2x  11  3x

Maintaining Your Skills Add or subtract as indicated. 3 2

5 10

76.   

1 3

2 5

80.   

75.   

79.   

1 3

4 12

77.   

3 4

3 7

81.   

2 7

1 14

78.   

3 8

1 16

1 6

4 3

82.   

2 5

5 10

Translating Translate each of the following into an equation, and then solve the equation. 83. The sum of x and 12 is 30.

84. The difference of x and 12 is 30.

85. The difference of 8 and 5 is equal to the sum of x and 7.

86. The sum of 8 and 5 is equal to the difference of x and 7.

The Multiplication Property of Equality In this section we will continue to solve equations in one variable. We will again use the addition property of equality, but we will also use another property—the multiplication property of equality—to solve the equations in this section. We will

8.3 Objectives A Use the multiplication property of equality to solve equations.

state the multiplication property of equality and then see how it is used by looking at some examples. The most popular Internet video download of all time was a Star Wars movie trailer. The video was compressed so it would be small enough for people to

Examples now playing at

download over the Internet. In movie theaters, a film plays at 24 frames per sec-

MathTV.com/books

ond. Over the Internet, that number is sometimes cut in half, to 12 frames per second, to make the file size smaller. x

We can use the equation 240  12 to find the number of total frames, x, in a 240-second movie clip that plays at 12 frames per second.

A Multiplication Property of Equality Multiplication Property of Equality Let A, B, and C represent algebraic expressions, with C not equal to 0. AB

If

AC  BC

then

In words: Multiplying both sides of an equation by the same nonzero quantity never changes the solution to the equation.

Now, because division is defined as multiplication by the reciprocal, we are also free to divide both sides of an equation by the same nonzero quantity and always be sure we have not changed the solution to the equation.

PRACTICE PROBLEMS

EXAMPLE 1 SOLUTION

1 Solve for x:  x  3 2 Our goal here is the same as it was in Section 8.2. We want to iso-

1 3

1. Solve for x:  x  5

1

late x (that is, 1x) on one side of the equation. We have 2x on the left side. If we multiply both sides by 2, we will have 1x on the left side. Here is how it looks: 1 x  3 2

 

1 2  x  2(3) 2

Multiply both sides by 2

x6

Multiplication

1

To see why 2(2x) is equivalent to x, we use the associative property:

  



1 1 2 x  2   x 2 2

Associative property

1x

1 2  1 2

x

1xx

Although we will not show this step when solving problems, it is implied. Answer 1. 15

8.3 The Multiplication Property of Equality

541

542

Chapter 8 Solving Equations

1 2. Solve for a:  a37 5

EXAMPLE 2

1 Solve for a:  a  2  7 3 1 SOLUTION We begin by adding 2 to both sides to get  a by itself. We then 3 multiply by 3 to solve for a. 1 a  2  7 3 1  a  2  (2)  7  (2) 3

Add 2 to both sides

1 a  5 3

Addition

1 3  a  3  5 3

Multiply both sides by 3

a  15

Multiplication

We can check our solution to see that it is correct: a  15

When the equation

1 a  2  7 3

becomes

1  (15)  2  7 3 527 77

3 3. Solve for y:  y6 5

A true statement

EXAMPLE 3

2 Solve for y:  y  12 3 SOLUTION In this case we multiply each side of the equation by the reciprocal 3 2 of  , which is  . 3 2 2  y  12 3

 

3 2 3   y   (12) 2 3 2 y  18 The solution checks because

2  3

of 18 is 12.

Note The reciprocal of a negative number is also a negative number. Remember, reciprocals are two numbers that have a product of 1. Since 1 is a positive number, any two numbers we multiply to get 1 must both have the same sign. Here are some negative numbers and their reciprocals: 1 The reciprocal of 2 is   . 2 1 The reciprocal of 7 is   . 7 1 The reciprocal of   is 3. 3 3 4 The reciprocal of   is   . 4 3 Answers 2. 20 3. 10

9 5 The reciprocal of   is   . 5 9

543

8.3 The Multiplication Property of Equality

EXAMPLE 4 SOLUTION

4 8 Solve for x:   x   5 15

3 4

6 5

4. Solve for x:  x  

4 5 The reciprocal of   is  . 5 4 8 4 x   5 15





 

5 5 8 4  x    5 4 4 15 2 x   3

Many times, it is convenient to divide both sides by a nonzero number to solve an equation, as the next example shows.

EXAMPLE 5 SOLUTION

Solve for x: 4x  20

5. Solve for x: 6x  42

If we divide both sides by 4, the left side will be just x, which is what

we want. It is okay to divide both sides by 4 because division by 4 is equivalent to 1

multiplication by 4, and the multiplication property of equality states that we can multiply both sides by any number so long as it isn’t 0.

Note

4x  20 4x 20    4 4 x  5

If we multiply each side by 41, the solution looks like this:

1 1 (4x)  (20) 4 4

Divide both sides by 4

1

Division

4x Because 4x means “4 times x,” the factors in the numerator of  are 4 and x. 4

4  4 x  5 1x  5 x  5

Because the factor 4 is common to the numerator and the denominator, we divide it out to get just x.

EXAMPLE 6 SOLUTION

6. Solve for x: 5x  6  14

Solve for x: 3x  7  5

We begin by adding 7 to both sides to reduce the left side to 3x. 3x  7  5 3x  7  (7)  5  (7) 3x  12 3x 12    3 3 x4

Add 7 to both sides Addition Divide both sides by 3 Division

With more complicated equations we simplify each side separately before applying the addition or multiplication properties of equality. The examples below illustrate.

EXAMPLE 7 SOLUTION

Solve for x: 5x  8x  3  4  10

7. Solve for x: 3x  7x  5  3  18

We combine similar terms to simplify each side and then solve as

usual. 5x  8x  3  4  10 3x  3  6 3x  3  (3)  6  (3) 3x  9 3x 9    3 3 x3

Simplify each side Add 3 to both sides Addition Divide both sides by 3 Division

Answers 8 5

4.  5. 7 6. 4 7. 5

544

8. Solve for x: 5  4  2x  11  3x

Chapter 8 Solving Equations

EXAMPLE 8 SOLUTION

Solve for x: 8  11  4x  11  3x

We begin by simplifying each side separately. 8  11  4x  11  3x 3  7x  11 3  11  7x  11  11 14  7x 14 7x    7 7

Simplify both sides Add 11 to both sides Addition Divide both sides by 7

2  x or x  2 Again, it makes no difference which side of the equation x ends up on, so long as it is just one x.

COMMON MISTAKES Before we end this section, we should mention a very common mistake made by students when they first begin to solve equations. It involves trying to subtract away the number in front of the variable—like this: 7x  21 7x  7  21  7

Add 7 to both sides

x  14 m88888 Mistake The mistake is not in trying to subtract 7 from both sides of the equation. The mistake occurs when we say 7x  7  x. It just isn’t true. We can add and subtract only similar terms. The terms 7x and 7 are not similar, because one contains x and the other doesn’t. The correct way to do the problem is like this: 7x  21 7x 21    Divide both sides by 7 7 7 x3

Division

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. True or false? Multiplying both sides of an equation by the same nonzero quantity will never change the solution to the equation. 2. If we were to multiply the right side of an equation by 2, then the left side should be multiplied by . 3. Dividing both sides of the equation 4x  20 by 4 is the same as multiplying both sides by what number?

Answer 8. 2

8.3 Problem Set

545

Problem Set 8.3 A Use the multiplication property of equality to solve each of the following equations. In each case, show all the steps. [Examples 1, 3–5] 1 4

3.  x  3

2.  x  7

1 3

5.   x  2

3 4

9.  y  12

3 5

1 2

1 3

1.  x  2

9 10

1 6

1 3

7.  x  1

6.   x  5

2 3

10.  y  18

4 5

8 15

1 5

4.  x  6

1 2

8.  x  4

11. 3a  48

12. 2a  28

13.   x  

14.   x   

15. 5x  35

16. 7x  35

17. 8y  64

18. 9y  27

19. 7x  42

20. 6x  42

546

Chapter 8 Solving Equations

A Using the addition property of equality first, solve each of the following equations. [Examples 2, 6] 21. 3x  1  5

22. 2x  4  6

23. 4a  3  9

25. 6x  5  19

26. 7x  5  30

27.  a  3  5

28.  a  2  7

31. 2x  4  20

32. 3x  5  26

1 4

29.  a  5  2

2 3

1 5

30.  a  3  7

3 4

1 3

24. 5a  10  50

1 2

33.  x  4  6

34.  x  2  7

35. 11a  4  29

36. 12a  1  47

37. 3y  2  1

38. 2y  8  2

39. 2x  5  7

40. 3x  6  36

A Simplify each side of the following equations first, then solve. [Examples 7, 8] 41. 2x  3x  5  7  3

42. 4x  5x  8  6  4

43. 4x  7  2x  9  10

44. 5x  6  3x  6  8

45. 3a  2a  a  7  13

46. 8a  6a  a  8  14

47. 5x  4x  3x  4  8

48. 4x  8x  2x  15  10

49. 5  18  3y  2y  1

50. 7  16  4y  3y  2

8.3 Problem Set

547

Find the value of x for each of the figures, given the perimeter.

51. P  72

52. P  96

2x

3x

53. P  80

54. P  64

5x

3x

2x

3x

Applying the Concepts 55. Cars The chart shows the fastest cars in America. To convert miles per hour to feet per second we use the formula y 

15  x 22

where x is the car’s speed in feet per

56. Mountains The map shows the heights of the tallest mountains in the world. To convert the heights of the mountains into miles, we use the formula y  5,280x,

second and y is the speed in miles per hour. Find the

where y is in feet and x is in miles. Find the height of K2

speed of the Ford GT in feet per second. Round to the

in miles. Round to the nearest tenth of a mile.

nearest tenth.

The Greatest Heights

Ready for the Races

K2 28,238 ft Mount Everest 29,035 ft Kangchenjunga 28,208 ft

Ford GT 205 mph Evans 487 210 mph Saleen S7 Twin Turbo 260 mph SSC Ultimate Aero 273 mph

PAKISTAN

NEP AL

INDIA Source: Forbes.com

Source: Forrester Research, 2005

CHINA

548

Chapter 8 Solving Equations

57. MP3 Players Southwest Electronics tracked the number

58. Part-time Tuition Costs Many two-year colleges have a

of MP3 players it sold each month for a year. The store

large number of students who take courses on a part-

manager found that when he raised the price of the

time basis. Students pay a charge for each credit hour

MP3 players just slightly, sales went down. He used the

taken plus an activity fee. Suppose the equation

equation 60  2x  130 to determine the price x he

$1960  $175x  $35 can be used to determine the

needs to charge if he wants to sell 60 MP3 players a

number of credit hours a student is taking during the

month. Solve this equation.

upcoming semester. Solve this equation.

59. Super Bowl XLII According to Nielsen Media Research,

60. Blending Gasoline In an attempt to save money at the

the New York Giants’ victory over the New England Pa-

gas pump, customers will combine two different octane

triots in Super Bowl XLII was the most watched Super

gasolines to get a blend that is slightly higher in octane

Bowl ever, with 3 million more viewers than the previ-

than regular gas but not as expensive as premium gas.

ous record for Super Bowl XXX in 1996. The equation

The equation 14x  120  6x  200 can be used to find

192,000,000  2x  3,000,000 shows that the total

out how many gallons of one octane are needed. Solve

number of viewers for both Super Bowl games was 192

this equation.

million. Solve for x to determine how many viewers watched Super Bowl XLII.

OCTANE 1

OCTANE BLEND

OCTANE 2

14x + 120 ‒ 6x = 200

192,000,000 viewers total

Maintaining Your Skills Translations Translate each sentence below into an equation, then solve the equation. 61. The sum of 2x and 5 is 19.

62. The sum of 8 and 3x is 2.

63. The difference of 5x and 6 is 9.

64. The difference of 9 and 6x is 21.

Getting Ready for the Next Section Apply the distributive property to each of the following expressions.

65. 2(3a  8)

66. 4(2a  5)

67. 3(5x  1)

68. 2(7x  3)

Simplify each of the following expressions as much as possible.

69. 3(y  5)  6

70. 5(y  3)  7

71. 6(2x  1)  4x

72. 8(3x  2)  4x

Linear Equations in One Variable

8.4 Objectives A Solve linear equations with one

Introduction . . .

variable.

ment, created around 1650

BC,

that contains

some mathematical riddles. One problem on the Rhind Papyrus asked the reader to find a quantity such that when it is added to onefourth of itself the sum is 15. The equation that describes this situation is 1 x  x  15 4

Bridgeman Art Library/Getty Images

The Rhind Papyrus is an ancient Egyptian docu-

B

Solve linear equations involving fractions and decimals.

C

Solve application problems using linear equations in one variable.

Examples now playing at

As you can see, this equation contains a fraction. One of the topics we will dis-

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cuss in this section is how to solve equations that contain fractions. In this chapter we have been solving what are called linear equations in one variable. They are equations that contain only one variable, and that variable is always raised to the first power and never appears in a denominator. Here are some examples of linear equations in one variable: 3x  2  17,

7a  4  3a  2,

2(3y  5)  6

Because of the work we have done in the first three sections of this chapter, we are now able to solve any linear equation in one variable. The steps outlined below can be used as a guide to solving these equations.

A Solving Linear Equations with One variable Strategy Solving a Linear Equation with One Variable Step 1: Simplify each side of the equation as much as possible. This step is done using the commutative, associative, and distributive properties.

Step 2: Use the addition property of equality to get all variable terms on one side of the equation and all constant terms on the other, and then

Note

Once you have some practice at solving equations, these steps will seem almost automatic. Until that time, it is a good idea to pay close attention to these steps.

combine like terms. A variable term is any term that contains the variable. A constant term is any term that contains only a number.

Step 3: Use the multiplication property of equality to get the variable by itself on one side of the equation.

Step 4: Check your solution in the original equation if you think it is necessary.

EXAMPLE 1 SOLUTION

PRACTICE PROBLEMS Solve: 3(x  2)  9

1. Solve: 4(x  3)  8

We begin by applying the distributive property to the left side:

Step 1 Step 2

Step 3



3(x  2)  9 3x  6  9

Distributive property

3x  6  (6)  9  (6)

Add 6 to both sides Addition

3x  15 3x 15    3 3 x  5

Divide both sides by 3 Division

8.4 Linear Equations in One Variable

Answer 1. 5

549

550

Chapter 8 Solving Equations This general method of solving linear equations involves using the two properties developed in Sections 8.2 and 8.3. We can add any number to both sides of an equation or multiply (or divide) both sides by the same nonzero number and always be sure we have not changed the solution to the equation. The equations may change in form, but the solution to the equation stays the same. Looking back to Example 1, we can see that each equation looks a little different from the preceding one. What is interesting, and useful, is that each of the equations says the same thing about x. They all say that x is 5. The last equation, of course, is the easiest to read. That is why our goal is to end up with x isolated on one side of the equation.

2. Solve: 6a  7  4a  3

EXAMPLE 2 SOLUTION

Solve: 4a  5  2a  7

Neither side can be simplified any further. What we have to do is get

the variable terms (4a and 2a) on the same side of the equation. We can eliminate the variable term from the right side by adding 2a to both sides:

Step 2

Step 3

3. Solve: 5(x  2)  3  12

EXAMPLE 3 SOLUTION

Step 1 Step 2 Step 3

EXAMPLE 4 SOLUTION

4a  (2a)  5  2a  (2a)  7 2a  5  7 2a  5  (5)  7  (5) 2a  12 2a 12    2 2

Add 2a to both sides Addition Add 5 to both sides Addition Divide by 2

a  6

Division

Solve: 2(x  4)  5  11

We begin by applying the distributive property to multiply 2 and

x  4:

4. Solve: 3(4x  5)  6  3x  9

4a  5  2a  7



2(x  4)  5  11 2x  8  5  11 2x  3  11 2x  3  3  11  3 2x  8 2x 8    2 2 x  4

Distributive property Addition Add 3 to both sides Addition Divide by 2 Division

Solve: 5(2x  4)  3  4x  5

We apply the distributive property to multiply 5 and 2x  4. We then

combine similar terms and solve as usual:

Step 1

Answers 2. 5 3. 1 4. 2

Step 2

Step 3

5(2x  4)  3  4x  5 10x  20  3  4x  5 10x  17  4x  5 10x  (4x)  17  4x  (4x)  5 6x  17  5 6x  17  17  5  17 6x  12 6x 12    6 6 x2

Distributive property Simplify the left side Add 4x to both sides Addition Add 17 to both sides Addition Divide by 6 Division

551

8.4 Linear Equations in One Variable

B Equations Involving Fractions We will now solve some equations that involve fractions. Because integers are usually easier to work with than fractions, we will begin each problem by clearing the equation we are trying to solve of all fractions. To do this, we will use the multiplication property of equality to multiply each side of the equation by the LCD for all fractions appearing in the equation. Here is an example.

EXAMPLE 5 SOLUTION

x x Solve the equation     8. 2 6 x x The LCD for the fractions 2 and 6 is 6. It has the property that both 2

x 3

x 6

5. Solve:     9

and 6 divide it evenly. Therefore, if we multiply both sides of the equation by 6, we will be left with an equation that does not involve fractions.

  x x 6   6   6(8) 2 6

x x 6     6(8) 2 6

3x  x  48 4x  48 x  12

Multiply each side by 6 Apply the distributive property Multiplication Combine similar terms Divide each side by 4

We could check our solution by substituting 12 for x in the original equation. If we do so, the result is a true statement. The solution is 12. As you can see from Example 5, the most important step in solving an equation that involves fractions is the first step. In that first step we multiply both sides of the equation by the LCD for all the fractions in the equation. After we have done so, the equation is clear of fractions because the LCD has the property that all the denominators divide it evenly.

EXAMPLE 6 SOLUTION

1 3 Solve the equation 2x    . 2 4 This time the LCD is 4. We begin by multiplying both sides of the

1 4

5 8

6. Solve: 3x    

equation by 4 to clear the equation of fractions.



   1 3 4(2x)  4   4  2 4 1 3 4 2x    4  2 4

8x  2  3

Multiply each side by the LCD, 4 Apply the distributive property Multiplication

8x  1

Add 2 to each side

1 x   8

Divide each side by 8

4 x

11 5

7. Solve:   3  

EXAMPLE 7 SOLUTION

3 1 Solve for x:   2  . (Assume x is not 0.) x 2 This time the LCD is 2x. Following the steps we used in Examples 5

and 6, we have





  3 1 2x   2x(2)  2x  x 2 3 1 2x   2  2x  x 2

6  4x  x 6  3x 2  x

Multiply through by the LCD, 2x Distributive property Multiplication Add 4x to each side Divide each side by 3

Answers 1 5. 18 6.  7. 5 8

552

Chapter 8 Solving Equations

Equations Containing Decimals 1 5

8. Solve: x  2.4  8.3

EXAMPLE 8 SOLUTION

1 Solve: x  3.78  2.52 2 We begin by adding 3.78 to each side of the equation. Then we

multiply each side by 2. 1 x  3.78  2.52 2 1 x  3.78  3.78  2.52  3.78 2

Add 3.78 to each side

1 x  6.30 2

 

1 2 x  2(6.30) 2

Multiply each side by 2

x  12.6

9. Solve: 7a  0.18  2a  0.77

EXAMPLE 9 SOLUTION

Solve: 5a  0.42  3a  0.98

We can isolate a on the left side of the equation by adding 3a to

each side. 5a  3a  0.42  3a  3a  0.98

Add 3a to each side

8a  0.42  0.98 8a  0.42  0.42  0.98  0.42

Add 0.42 to each side

8a  1.40 8a 1.40    8 8

Divide each side by 8

a  0.175

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. Apply the distributive property to the expression 3(x  4). 2. Write the equation that results when 4a is added to both sides of the equation below. 6a  9  4a  3 1 1 3 3. Solve the equation 2x     by first adding  to each side. 2 2 4 Compare your answer with the solution to the equation shown in Example 6.

Answers 8. 53.5 9. 0.19

8.4 Problem Set

Problem Set 8.4 A Solve each equation using the methods shown in this section. [Examples 1–4] 1. 5(x  1)  20

2. 4(x  2)  24

3. 6(x  3)  6

4. 7(x  2)  7

5. 2x  4  3x  7

6. 5x  3  2x  (3)

7. 7y  3  4y  15

8. 3y  5  9y  8

9. 12x  3  2x  17

10. 15x  1  4x  20

11. 6x  8  x  8

12. 7x  5  x  5

13. 7(a  1)  4  11

14. 3(a  2)  1  4

15. 8(x  5)  6  18

16. 7(x  8)  4  10

17. 2(3x  6)  1  7

18. 5(2x  4)  8  38

19. 10(y  1)  4  3y  7

20. 12(y  2)  5  2y  1

21. 4(x  6)  1  2x  9

22. 7(x  4)  3  5x  9

23. 2(3x  1)  4(x  1)

24. 7(x  8)  2(x  13)

25. 3a  4  2(a  5)  15

26. 10a  3  4(a  1)  1

27. 9x  6  3(x  2)  24

28. 8x  10  4(x  3)  2

29. 3x  5  11  2(x  6)

30. 5x  7  7  2(x  3)

553

554

Chapter 8 Solving Equations

B Solve each equation by first finding the LCD for the fractions in the equation and then multiplying both sides of the equation by it. (Assume x is not 0 in Problems 39–46.) [Examples 5–7] x 3

x 6

x 2

31.     5

1 2

1 4

1 3

35. 3x    

4 x

1 5

3 x

2 x

x 4

32.     3

1 6

36. 3x    

39.   

1 5

x 3

x 3

1 2

34.   x  8

1 2

x 2

37.     

3 x

4 3

2 3

38.     

2 3

6 x

41.   1  

44.     2

7 x

1 x

45.     

46.     

48. 2x  3.8  7.7

49. 0.02  5y  0.3

50. 0.8  10y  0.7

40.   

43.     

x 5

33.   x  4

1 x

2 x

1 2

4 x

1 x

42.   3  

1 4

3 x

4 5

1 5

Solve each equation.

47. 4x  4.7  3.5

1 3

1 7

51. x  2.99  1.02

52. x  2.87  3.01

53. 7n  0.32  5n  0.56

54. 6n  0.88  2n  0.77

55. 3a  4.6  7a  5.3

56. 2a  3.3  7a  5.2

57. 0.5x  0.1(x  20)  3.2

58. 0.1x  0.5(x  8)  7

Find the value of x for each of the figures, given the perimeter.

59. P  36

60. P  30

2x  3 x

x

x 2x  2

x6

61. P  16

62. P  60

2x  6 x

x

x 2x  4

x1

8.4 Problem Set

C

555

Applying the Concepts

63. Skyscrapers The chart shows the heights of the three

64. Sound The chart shows the decibel level of various

tallest buildings in the world. The height of the Empire

sounds. The human threshold of pain relative to the

State Building relative to the Petronas Towers can be

decibel level at a football stadium is given by the equa-

given by the equation 1483  233  x. What is the

tion 117  x  3. What is the human threshold of pain?

height of the Empire State Building?

Sounds Around Us

Such Great Heights Petronas Tower 1 & 2 Kuala Lumpur, Malaysia

Taipei 101 Taipei, Taiwan

Normal Conversation

1,483 ft

60 dB

Sears Tower Chicago, USA

1,670 ft

1,450 ft

Football Stadium

117 dB

Blue Whale Source: www.tenmojo.com

188 dB

Source: www.4to40.com

65. Geometry The figure shows part of a room. From a point

66. Rhind Papyrus As we mentioned in the introduction to

on the floor, the angle of elevation to the top of the win-

this section, the Rhind Papyrus was created around

dow is 45°, while the angle of elevation to the ceiling

1650 BC and contains the riddle, “What quantity when

above the window is 58°. Solving either of the equations

added to one-fourth of itself becomes 15?” This riddle

58  x  45 or 45  x  58 will give us the number of de-

can be solved by finding x in the equation below. Solve

grees in the angle labeled x°. Solve both equations.

this equation. 1 x   x  15 4

Window



58° 45° Floor

67. Math Tutoring Several students on campus decide to

Bridgeman Art Library/ Getty Images

Ceiling

68. Shopping for a Calculator You find that you need to pur-

start a small business that offers tutoring services to stu-

chase a specific calculator for your college mathematics

dents enrolled in mathematics courses. The following

class. The equation $18.75  p  4 p shows the price

equation shows the amount of money they collected at

charged by the college bookstore for a calculator after

the end of the month, assuming expenses of $400 and a

it has been marked up. How much did the bookstore

charge of $30 an hour per student. Solve the equation

pay the manufacturer for the calculator?

$500  $30x  400 to determine the number of hours students came in for tutoring in one month.

1

556

Chapter 8 Solving Equations

Getting Ready for the Next Section Write the mathematical expressions that are equivalent to each of the following English phrases.

69. The sum of a number and 2

70. The sum of a number and 5

71. Twice a number

72. Three times a number

73. Twice the sum of a number and 6

74. Three times the sum of a number and 8

75. The difference of x and 4

76. The difference of 4 and x

77. The sum of twice a number and 5

78. The sum of three times a number and 4

Maintaining Your Skills Place the correct symbol,  or , between the numbers.

79. 0.02

0.2

80. 0.3

0.03

81. 0.45

0.4

82. 0.5

0.56

Write the numbers in order from smallest to largest.

83. 0.01 0.013 0.03 0.003 0.031 0.001

84. 0.062 0.006 0.002 0.02 0.06 0.026

Extending the Concepts 85. Admission to the school basketball game is $4 for students and $6 for general admission. For the first game of the season, 100 more student tickets than general admission tickets were sold. The total amount of money collected was $2,400.

a. Write an equation that will help us find the number of students in attendance. b. Solve this equation for x. c. What was the total attendance for the game?

Applications

8.5 Objectives A Set up and solve number problems

Introduction . . . As you begin reading through the examples in this section, you may find yourself asking why some of these problems seem so contrived. The title of the section is “Applications,” but many of the problems here don’t seem to have much to do with real life. You are right about that. Example 5 is what we refer to as an “age problem.” Realistically, it is not the kind of problem you would expect to find if you

using linear equations.

B

Set up and solve geometry problems using linear equations.

C

Set up and solve age problems using linear equations.

choose a career in which you use algebra. However, solving age problems is good practice for someone with little experience with application problems, because the solution process has a form that can be applied to all similar age problems. To begin this section we list the steps used in solving application problems. We

Examples now playing at

call this strategy the Blueprint for Problem Solving. It is an outline that will overlay

MathTV.com/books

the solution process we use on all application problems.

Blueprint for Problem Solving Step 1: Read the problem, and then mentally list the items that are known and the items that are unknown.

Step 2: Assign a variable to one of the unknown items. (In most cases this will amount to letting x equal the item that is asked for in the problem.) Then translate the other information in the problem to expressions involving the variable.

Step 3: Reread the problem, and then write an equation, using the items and variables listed in Steps 1 and 2, that describes the situation.

Step 4: Solve the equation found in Step 3. Step 5: Write your answer using a complete sentence. Step 6: Reread the problem, and check your solution with the original words in the problem.

There are a number of substeps within each of the steps in our blueprint. For instance, with Steps 1 and 2 it is always a good idea to draw a diagram or picture if it helps you to visualize the relationship between the items in the problem. It is important for you to remember that solving application problems is more of an art than a science. Be flexible. No one strategy works all of the time. Try to stay away from looking for the “one way” to set up and solve a problem. Think of the blueprint for problem solving as guidelines that will help you organize your approach to these problems, rather than as a set of rules.

A Number Problems EXAMPLE 1 SOLUTION

PRACTICE PROBLEMS The sum of a number and 2 is 8. Find the number.

Using our blueprint for problem solving as an outline, we solve the

1. The sum of a number and 3 is 10. Find the number.

problem as follows:

Step 1

Read the problem, and then mentally list the items that are known and the items that are unknown. Known items:

The numbers 2 and 8

Unknown item:

The number in question

8.5 Applications

557

558

Chapter 8 Solving Equations

Step 2 Assign a variable to one of the unknown items. Then translate the other information in the problem to expressions involving the variable. Let x  the number asked for in the problem Then “The sum of a number and 2” translates to x  2.

Step 3 Reread the problem, and then write an equation, using the items and variables listed in Steps 1 and 2, that describes the situation. With all word problems, the word “is” translates to  . The sum of x and 2 is 8. x28

Step 4 Solve the equation found in Step 3. x28 x  2  (2)  8  (2)

Add 2 to each side

x6

Step 5 Write your answer using a complete sentence. The number is 6.

Step 6 Reread the problem, and check your solution with the original words in the problem. The sum of 6 and 2 is 8.

A true statement

To help with other problems of the type shown in Example 1, here are some common English words and phrases and their mathematical translations. English

Algebra

The sum of a and b The difference of a and b The product of a and b The quotient of a and b Of Is A number 4 more than x 4 times x 4 less than x

ab ab ab a  b  (multiply)  (equals) x x4 4x x4

You may find some examples and problems in this section and the problem set that follows that you can solve without using algebra or our blueprint. It is very important that you solve those problems using the methods we are showing here. The purpose behind these problems is to give you experience using the blueprint as a guide to solving problems written in words. Your answers are much less important than the work that you show in obtaining your answer.

2. If 4 is added to the sum of twice a number and three times the number, the result is 34. Find the number.

EXAMPLE 2

If 5 is added to the sum of twice a number and three times

the number, the result is 25. Find the number.

SOLUTION Step 1 Read and list. Known items:

Answer 1. The number is 7.

The numbers 5 and 25, twice a number, and three times a number

Unknown item:

The number in question

559

8.5 Applications

Step 2 Assign a variable and translate the information. Let x  the number asked for in the problem. Then “The sum of twice a number and three times the number” translates to 2x  3x.

Step 3 Reread and write an equation. is 25

and three times the number

7n

887

the sum of twice a number

888

887n 888

added to

88888n 88888n

5



5

2x  3x

 25

Step 4 Solve the equation. 5  2x  3x  25 5x  5  25 5x  5  (5)  25  (5) 5x  20 5x 20    5 5

Simplify the left side Add 5 to both sides Addition Divide by 5

x4

Step 5 Write your answer. The number is 4.

Step 6 Reread and check. Twice 4 is 8, and three times 4 is 12. Their sum is 8  12  20. Five added to this is 25. Therefore, 5 added to the sum of twice 4 and three times 4 is 25.

B Geometry Problems EXAMPLE 3

The length of a rectangle is three times the width. The

perimeter is 72 centimeters. Find the width and the length.

SOLUTION Step 1 Read and list. Known items:

3. The length of a rectangle is twice the width. The perimeter is 42 centimeters. Find the length and the width.

The length is three times the width. The perimeter is 72 centimeters.

Unknown items:

The length and the width

Step 2 Assign a variable, and translate the information. We let x  the width. Because the length is three times the width, the length must be 3x. A picture will help.

Rectangle

x (width)

3x (length) FIGURE 1 Answer 2. The number is 6.

560

Chapter 8 Solving Equations

Step 3 Reread and write an equation. Because the perimeter is the sum of the sides, it must be x  x  3x  3x (the sum of the four sides). But the perimeter is also given as 72 centimeters. Hence, x  x  3x  3x  72

Step 4 Solve the equation. x  x  3x  3x  72 8x  72 x9

Step 5 Write your answer. The width, x, is 9 centimeters. The length, 3x, must be 27 centimeters.

Step 6 Reread and check. From the diagram below, we see that these solutions check:

Perimeter is 72

Length  3  Width

9  9  27  27  72

27  3  9

27 9

9 27 FIGURE 2

Next we review some facts about triangles that we introduced in a previous chapter.

FACTS FROM GEOMETRY Labeling Triangles and the Sum of the Angles in a Triangle One way to label the important parts of a triangle is to label the vertices with capital letters and the sides with small letters, as shown in Figure 3.

B

a

c

A

b

C

FIGURE 3 In Figure 3, notice that side a is opposite vertex A, side b is opposite vertex B, and side c is opposite vertex C. Also, because each vertex is the vertex of one of the angles of the triangle, we refer to the three interior angles as A, B, and C. In any triangle, the sum of the interior angles is 180°. For the triangle shown in Figure 3, the relationship is written Answer 3. The width is 7 cm, and the length is 14 cm.

A  B  C  180°

561

8.5 Applications

EXAMPLE 4

The angles in a triangle are such that one angle is twice

the smallest angle, while the third angle is three times as large as the smallest angle. Find the measure of all three angles.

SOLUTION Step 1 Read and list. Known items:

4. The angles in a triangle are such that one angle is three times the smallest angle, while the largest angle is five times the smallest angle. Find the measure of all three angles.

The sum of all three angles is 180°; one angle is twice the smallest angle; and the largest angle is three times the smallest angle.

Unknown items:

The measure of each angle

Step 2 Assign a variable and translate information. Let x be the smallest angle, then 2x will be the measure of another angle, and 3x will be the measure of the largest angle.

Step 3 Reread and write an equation. When working with geometric objects, drawing a generic diagram will sometimes help us visualize what it is that we are asked to find. In Figure 4, we draw a triangle with angles A, B, and C.

C

b

A

a

B

c

FIGURE 4 We can let the value of A  x, the value of B  2x, and the value of C  3x. We know that the sum of angles A, B, and C will be 180°, so our equation becomes x  2x  3x  180°

Step 4 Solve the equation. x  2x  3x  180° 6x  180° x  30°

Step 5 Write the answer. The smallest angle A measures 30° Angle B measures 2x, or 2(30°)  60° Angle C measures 3x, or 3(30°)  90°

Step 6 Reread and check. The angles must add to 180°: A  B  C  180° 30°  60°  90°  180° 180°  180°

Our answers check

Answer 4. The angles are 20°, 60°, and 100°.

562

Chapter 8 Solving Equations

C Age Problem 5. Joyce is 21 years older than her son Travis. In six years the sum of their ages will be 49. How old are they now?

EXAMPLE 5

Jo Ann is 22 years older than her daughter Stacey. In six

years the sum of their ages will be 42. How old are they now?

SOLUTION Step 1 Read and list: Known items:

Jo Ann is 22 years older than Stacey. Six years from now their ages will add to 42.

Unknown items:

Their ages now

Step 2 Assign a variable and translate the information. Let x  Stacey’s age now. Because Jo Ann is 22 years older than Stacey, her age is x  22.

Step 3 Reread and write an equation. As an aid in writing the equation we use the following table: Now

In Six years

Stacey

x

x6

Jo Ann

x  22

x  28

Their ages in six years will be their ages now plus 6

Because the sum of their ages six years from now is 42, we write the equation as (x  6)  (x  28)  42 h h

Stacey’s age in 6 years

Jo Ann’s age in 6 years

Step 4 Solve the equation. x  6  x  28  42 2x  34  42 2x  8 x4

Step 5 Write your answer. Stacey is now 4 years old, and Jo Ann is 4  22  26 years old.

Step 6 Reread and check. To check, we see that in six years, Stacey will be 10, and Jo Ann will be 32. The sum of 10 and 32 is 42, which checks.

Car Rental Problem 6. If a car were rented from the company in Example 6 for 2 days and the total charge was $41, how many miles was the car driven?

EXAMPLE 6

A car rental company charges $11 per day and 16 cents

per mile for their cars. If a car were rented for 1 day and the charge was $25.40, how many miles was the car driven?

SOLUTION Step 1 Read and list. Known items:

Charges are $11 per day and 16 cents per mile. Car is rented for 1 day. Total charge is $25.40.

Unknown items: Answer 5. Travis is 8; Joyce is 29.

How many miles the car was driven

563

8.5 Applications

Step 2 Assign a variable and translate information. If we let x  the number of miles driven, then the charge for the number of miles driven will be 0.16x, the cost per mile times the number of miles.

Step 3 Reread and write an equation. To find the total cost to rent the car, we add 11 to 0.16x. Here is the equation that describes the situation: 16 cents per mile

 Total cost



day



11

 0.16x

$11 per



25.40

Step 4 Solve the equation. To solve the equation, we add 11 to each side and then divide each side by 0.16. 11  (11)  0.16x  25.40  (11)

Add 11 to each side

0.16x  14.40 0.16x 14.40    0.16 0.16 x  90

Divide each side by 0.16 14.40  0.16  90

Step 5 Write the answer. The car was driven 90 miles. Step 6 Reread and check. The charge for 1 day is $11. The 90 miles adds 90($0.16)  $14.40 to the 1-day charge. The total is $11  $14.40  $25.40, which checks with the total charge given in the problem.

Coin Problem EXAMPLE 7

Diane has $1.60 in dimes and nickels. If she has 7 more

dimes than nickels, how many of each coin does she have?

SOLUTION Step 1 Read and list. Known items:

7. Amy has $1.75 in dimes and quarters. If she has 7 more dimes than quarters, how many of each coin does she have?

We have dimes and nickels. There are 7 more dimes than nickels, and the total value of the coins is $1.60.

Unknown items:

How many of each type of coin Diane has

Step 2 Assign a variable and translate information. If we let x  the number of nickels, then the number of dimes must be x  7, because Diane has 7 more dimes than nickels. Because each nickel is worth 5 cents, the amount of money she has in nickels is 0.05x. Similarly, because each dime is worth 10 cents, the amount of money she has in dimes is 0.10(x  7). Here is a table that summarizes what we have so far:

Number of Value of

Nickels

Dimes

x

x7

0.05x

0.10(x  7)

Answer 6. The car was driven 118.75 miles.

564

Chapter 8 Solving Equations

Step 3 Reread and write an equation. Because the total value of all the coins is $1.60, the equation that describes this situation is Amount of money



Amount of money in dimes



Total amount of money



in nickels



0.05x

0.10(x  7)



1.60

Step 4 Solve the equation. This time, let’s show only the essential steps in the solution. 0.05x  0.10x  0.70  1.60 0.15x  0.70  1.60 0.15x  0.90 x6

Distributive property Add 0.05x and 0.10x to get 0.15x Add 0.70 to each side Divide each side by 0.15

Step 5 Write the answer. Because x  6, Diane has 6 nickels. To find the number of dimes, we add 7 to the number of nickels (she has 7 more dimes than nickels). The number of dimes is 6  7  13.

Step 6 Reread and check. Here is a check of our results. 6 nickels are worth 6($0.05)  $0.30 13 dimes are worth 13($0.10)  $1.30 The total value is

$1.60

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. What is the first step in solving a word problem? 2. Write a mathematical expression equivalent to the phrase “the sum of x and ten.” 3. Write a mathematical expression equivalent to the phrase “twice the sum of a number and ten.” 4. Suppose the length of a rectangle is three times the width. If we let x represent the width of the rectangle, what expression do we use to represent the length?

Answer 7. There are 3 quarters and 10 dimes.

8.5 Problem Set

565

Problem Set 8.5 Write each of the following English phrases in symbols using the variable x.

1. The sum of x and 3

2. The difference of x and 2

3. The sum of twice x and 1

4. The sum of three times x and 4

5. Five x decreased by 6

6. Twice the sum of x and 5

7. Three times the sum of x and 1

8. Four times the sum of twice x and 1

9. Five times the sum of three x and 4

10. Three x added to the sum of twice x and 1

Use the six steps in the “Blueprint for Problem Solving” to solve the following word problems. You may recognize the solution to some of them by just reading the problem. In all cases, be sure to assign a variable and write the equation used to describe the problem. Write your answer using a complete sentence.

A

Number Problems

[Examples 1, 2]

11. The sum of a number and 3 is 5. Find the number.

12. If 2 is subtracted from a number, the result is 4. Find the number.

13. The sum of twice a number and 1 is 3. Find the number.

15. When 6 is subtracted from five times a number, the re-

14. If three times a number is increased by 4, the result is 8. Find the number.

16. Twice the sum of a number and 5 is 4. Find the number.

sult is 9. Find the number.

17. Three times the sum of a number and 1 is 18. Find the number.

19. Five times the sum of three times a number and 4 is 10. Find the number.

18. Four times the sum of twice a number and 6 is 8. Find the number.

20. If the sum of three times a number and two times the same number is increased by 1, the result is 16. Find the number.

566

B

Chapter 8 Solving Equations

Geometry Problems

[Examples 3, 4]

21. The length of a rectangle is twice its width. The perimeter is 30 meters. Find the length and the width.

23. The perimeter of a square is 32 centimeters. What is the length of one side?

22. The width of a rectangle is 3 feet less than its length. If the perimeter is 22 feet, what is the width?

24. Two sides of a triangle are equal in length, and the third side is 10 inches. If the perimeter is 26 inches, how long are the two equal sides?

25. Two angles in a triangle are equal, and their sum is

26. One angle in a triangle measures twice the smallest

equal to the third angle in the triangle. What are the

angle, while the largest angle is six times the smallest

measures of each of the three interior angles?

angle. Find the measures of all three angles.

1

27. The smallest angle in a triangle is 3 as large as the largest angle. The third angle is twice the smallest an-

28. One angle in a triangle is half the largest angle, but three times the smallest. Find all three angles.

gle. Find the three angles.

C

Age Problems

[Example 5]

29. Pat is 20 years older than his son Patrick. In 2 years, the sum of their ages will be 90. How old are they now?

30. Diane is 23 years older than her daughter Amy. In 5 years, the sum of their ages will be 91. How old are they now?

Now Patrick

In 2 Years

x

Pat

31. Dale is 4 years older than Sue. Five years ago the sum of their ages was 64. How old are they now?

Now Amy

In 5 Years

x

Diane

32. Pat is 2 years younger than his wife, Wynn. Ten years ago the sum of their ages was 48. How old are they now?

Renting a Car 33. A car rental company charges $10 a day and 16 cents

34. A car rental company charges $12 a day and 18 cents

per mile for their cars. If a car were rented for 1 day for

per mile to rent their cars. If the total charge for a

a total charge of $23.92, how many miles was it driven?

1-day rental were $33.78, how many miles was the car driven?

35. A rental company charges $9 per day and 15 cents a

36. A car rental company charges $11 a day and 18 cents

mile for their cars. If a car were rented for 2 days for a

per mile to rent their cars. If the total charge for a

total charge of $40.05, how many miles was it driven?

2-day rental were $61.60, how many miles was it driven?

8.5 Problem Set

567

Coin Problems 37. Mary has $2.20 in dimes and nickels. If she has 10

38. Bob has $1.65 in dimes and nickels. If he has 9 more

more dimes than nickels, how many of each coin does

nickels than dimes, how many of each coin does he

she have?

have?

39. Suppose you have $9.60 in dimes and quarters. How

40. A collection of dimes and quarters has a total value of

many of each coin do you have if you have twice as

$2.75. If there are 3 times as many dimes as quarters,

many quarters as dimes?

how many of each coin is in the collection?

Miscellaneous Problems 41. Magic Square The sum of the numbers in each row,

42. Magic Square The sum of the numbers in each row,

each column, and each diagonal of the square below is

each column, and each diagonal of the square below is

15. Use this fact, along with the information in the first

3. Use this fact, along with the information in the sec-

column of the square, to write an equation containing

ond row of the square, to write an equation containing

the variable x, then solve the equation to find x. Next,

the variable a, then solve the equation to find a. Next,

write and solve equations that will give you y and z.

write and solve an equation that will allow you to find the value of b. Next, write and solve equations that will

x

1

y

3

5

7

4

z

2

give you c and d.

43. Wages JoAnn works in the publicity office at the state

4

d

b

a

1

3

0

c

2

44. Ticket Sales Stacey is selling tickets to the school play.

university. She is paid $14 an hour for the first 35 hours

The tickets are $6 for adults and $4 for children. She

she works each week and $21 an hour for every hour

sells twice as many adult tickets as children’s tickets

after that. If she makes $574 one week, how many

and brings in a total of $112. How many of each kind of

hours did she work?

ticket did she sell?

45. Cars The chart shows the fastest cars in America. The

46. Skyscrapers The chart shows the heights of the three

maximum speed of an Evans 487 is twice the sum of

tallest buildings in the world. The Sears Tower is 80

the speed of a trucker and 45 miles per hour. What is

feet less than 5 times the height of the Statue of Liberty.

the speed of the trucker?

What is the height of the Statue of Liberty?

Ready for the Races

Such Great Heights Ford GT 205 mph

Taipei 101 Taipei, Taiwan

1,670 ft

Evans 487 210 mph

1,483 ft Sears Tower Chicago, USA

1,450 ft

Saleen S7 Twin Turbo 260 mph SSC Ultimate Aero 273 mph

Source: Forbes.com

Petronas Tower 1 & 2 Kuala Lumpur, Malaysia

Source: www.tenmojo.com

Getting Ready for the Next Section Simplify. 5 9

5 9

47.  (95  32)

48.  (77  32)

49. Find the value of 90  x when x  25.

50. Find the value of 180  x when x  25.

51. Find the value of 2x  6 when x  2

52. Find the value of 2x  6 when x  0.

Solve.

53. 40  2l  12

54. 80  2l  12

55. 6  3y  4

56. 8  3y  4

Maintaining Your Skills The problems below review some of the work you have done with percents. Change each fraction to a decimal and then to a percent. 3 4

57. 

5 8

58. 

1 5

7 10

59. 1

60. 

63. 3.4%

64. 125%

Change each percent to a fraction and a decimal.

61. 37%

62. 18%

65. What number is 15% of 135?

67. 12 is 16% of what number?

66. 19 is what percent of 38?

Evaluating Formulas Introduction . . . In mathematics a formula is an equation that contains more than one variable. The equation P  2w  2l is an example of a formula. This formula tells us the re-

8.6 Objectives A Solve a formula for a given variable. B Solve problems using the rate equation.

lationship between the perimeter P of a rectangle, its length l, and its width w. There are many formulas with which you may be familiar already. Perhaps you have used the formula d  r  t to find out how far you would go if you traveled at 50 miles an hour for 3 hours. If you take a chemistry class while you are in col-

Examples now playing at

lege, you will certainly use the formula that gives the relationship between the

MathTV.com/books

two temperature scales, Fahrenheit and Celsius: 9 F   C  32 5 Although there are many kinds of problems we can work using formulas, we will limit ourselves to those that require only substitutions. The examples that follow illustrate this type of problem.

A Formulas EXAMPLE 1

PRACTICE PROBLEMS The perimeter P of a rectangular livestock pen is 40 feet. If

1. Suppose the livestock pen in Example 1 has a perimeter of 80 feet. If the width is still 6 feet, what is the new length?

the width w is 6 feet, find the length.

6 feet

l

SOLUTION First we substitute 40 for P and 6 for w in the formula P  2l  2w. Then we solve for l : When the formula

P  40 and w  6 P  2l  2w

becomes

40  2l  2(6)

or

40  2l  12 28  2l 14  l

Multiply 2 and 6 Add 12 to each side Multiply each side by 21

To summarize our results, if a rectangular pen has a perimeter of 40 feet and a width of 6 feet, then the length must be 14 feet.

Answer 1. 34 feet

8.6 Evaluating Formulas

569

570

Chapter 8 Solving Equations

2. Use the formula in Example 2 to find C when F is 77 degrees.

Note

EXAMPLE 2

5

Use the formula C  9(F  32) to find C when F is 95

degrees.

SOLUTION Substituting 95 for F in the formula gives us the following: The formula we are using here,

F  95

When

5 the formula C   (F  32) 9

5 C  (F  32), 9

is an alternative form of the formula we mentioned in the introduction to this section:

becomes

5 C   (95  32) 9 5   (63) 9

9 F  C  32 5

Both formulas describe the same relationship between the two temperature scales. If you go on to take an algebra class, you will learn how to convert one formula into the other.

5 63     9 1 315   9  35 A temperature of 95 degrees Fahrenheit is the same as a temperature of 35 degrees Celsius.

3. Use the formula in Example 3 to

EXAMPLE 3

find y when x is 0.

Use the formula y  2x  6 to find y when x is 2.

SOLUTION Proceeding as we have in the previous examples, we have: When

x  2

the formula

y  2x  6

becomes

y  2(2)  6  4  6 2

In some cases evaluating a formula also involves solving an equation, as the next example illustrates. 4. Use the formula in Example 4 to find y when x is 3.

EXAMPLE 4

Find y when x is 3 in the formula 2x  3y  4.

SOLUTION First we substitute 3 for x ; then we solve the resulting equation for y. When the equation becomes

x3 2x  3y  4 2(3)  3y  4 6  3y  4 3y  2 2 y   3

Add 6 to each side Divide each side by 3

B Rate Equation Now we will look at some problems that use what is called the rate equation. You use this equation on an intuitive level when you are estimating how long it will take you to drive long distances. For example, if you drive at 50 miles per hour for 2 hours, you will travel 100 miles. Here is the rate equation: Answers 2. 25 degrees Celsius 10 3

4. 

Distance  rate  time, or d  r  t 3. 6

571

8.6 Evaluating Formulas The rate equation has two equivalent forms, one of which is obtained by solving for r, while the other is obtained by solving for t. Here they are: d d r   and t   t r The rate in this equation is also referred to as average speed.

EXAMPLE 5

At 1 P.M., Jordan leaves her house and drives at an average

speed of 50 miles per hour to her sister’s house. She arrives at 4 P.M.

a. How many hours was the drive to her sister’s house? b. How many miles from her sister does Jordan live? SOLUTION a. If she left at 1:00 P.M. and arrived at 4:00 P.M., we simply subtract 1 from 4 for an answer of 3 hours.

5. At 9 A.M. Maggie leaves her house and drives at an average speed of 60 miles per hour to her sister’s house. She arrives at 11 A.M. b. How many hours was the drive to her sister’s house? c. How many miles from her sister does Maggie live?

b. We are asked to find a distance in miles given a rate of 50 miles per hour and a time of 3 hours. We will use the rate equation, d  r  t, to solve this. We have: d  50 miles per hour  3 hours d  50(3) d  150 miles Notice that we were asked to find a distance in miles, so our answer has a unit of miles. When we are asked to find a time, our answer will include a unit of time, like days, hours, minutes, or seconds. When we are asked to find a rate, our answer will include units of rate, like miles per hour, feet per second, problems per minute, and so on.

FACTS FROM GEOMETRY Earlier we defined complementary angles as angles that add to 90°. That is, if x and y are complementary angles, then

90˚−x x

x  y  90° If we solve this formula for y, we obtain a formula equivalent to our original

Complementary angles

formula: y  90°  x Because y is the complement of x, we can generalize by saying that the complement of angle x is the angle 90°  x. By a similar reasoning process, we can say that the supplement of angle x is the angle 180°  x. To summarize, if x is an angle, then

180˚−x x

the complement of x is 90°  x, and the supplement of x is 180°  x

Supplementary angles

If you go on to take a trigonometry class, you will see these formulas again.

Answer 5. a. 2 hours b. 120 miles

572

6. Find the complement and the supplement of 35°.

Chapter 8 Solving Equations

EXAMPLE 6

Find the complement and the supplement of 25°.

SOLUTION We can use the formulas above with x  25°. The complement of 25° is 90°  25°  65°. The supplement of 25° is 180°  25°  155°.

Getting Ready for Class After reading through the preceding section, respond in your own words and in complete sentences. 1. 2. 3. 4.

Answer 6. Complement  55°; Supplement  145°

What is a formula? How do you solve a formula for one of its variables? What are complementary angles? What is the formula that converts temperature on the Celsius scale to temperature on the Fahrenheit scale?

8.6 Problem Set

573

Problem Set 8.6 A The formula for the area A of a rectangle with length l and width w is A  l  w. Find A if: [Examples 1–4] 1. l  32 feet and w  22 feet

3 2

3 4

3. l   inch and w   inch

2. l  22 feet and w  12 feet

3 5

3 10

4. l   inch and w   inch

The formula G  H  R tells us how much gross pay G a person receives for working H hours at an hourly rate of pay R. In Problems 5-8, find G.

5. H  40 hours and R  $6

6. H  36 hours and R  $8

1 2

7. H  30 hours and R  $9 

3 4

8. H  20 hours and R  $6 

Because there are 3 feet in every yard, the formula F  3  Y will convert Y yards into F feet. In Problems 9-12, find F.

9. Y  4 yards

10. Y  8 yards

1 3

2 3

11. Y  2  yards

12. Y  6  yards

If you invest P dollars (P is for principal ) at simple interest rate R for T years, the amount of interest you will earn is given by the formula I  P  R  T. In Problems 13 and 14, find I. 7 100

13. P  $1,000, R   , and T  2 years

6 100

1 2

14. P  $2,000, R   , and T  2  years

In Problems 15-18, use the formula P  2w  2l to find P.

15. w  10 inches and l  19 inches

3 4

7 8

17. w   foot and l   foot

16. w  12 inches and l  22 inches

1 2

3 2

18. w   foot and l   feet

574

Chapter 8 Solving Equations

We have mentioned the two temperature scales, Fahrenheit and Celsius. Table 1 is intended to give you a more intuitive idea of the relationship between the two temperatures scales.

TABLE 1

COMPARING TWO TEMPERATURE SCALES Situation Water freezes Room temperature Normal body temperature Water boils Bake cookies

Temperature (Fahrenheit)

Temperature (Celsius)

32°F 68°F 3 985°F 212°F 365°F

0°C 20°C 37°C 100°C 185°C

Table 2 gives the formulas, in both symbols and words, that are used to convert between the two scales.

TABLE 2

FORMULAS FOR CONVERTING BETWEEN TEMPERATURE SCALES To Convert From

Formula In Symbols

Formula In Words

Fahrenheit to Celsius

5 C  (F  32) 9

5 Subtract 32, then multiply by . 9

Celsius to Fahrenheit

9 F  C  32 5

9 Multiply by , then add 32. 5

5

19. Let F  212 in the formula C  9(F  32), and solve for

9

20. Let C  100 in the formula F  5C  32, and solve for F.

C. Does the value of C agree with the information in

Does the value of F agree with the information in Table

Table 1?

1?

5

21. Let F  68 in the formula C  9(F  32), and solve for C.

9

22. Let C  37 in the formula F  5C  32, and solve for F.

Does the value of C agree with the information in Table

Does the value of F agree with the information in Table

1?

1?

23. Find C when F is 32°.

24. Find C when F is 4°.

25. Find F when C is 15°.

26. Find F when C is 35°.

8.6 Problem Set

575

B Maximum Heart Rate In exercise physiology, a person’s maximum heart rate, in beats per minute, is found by subtracting his age in years from 220. So, if A represents your age in years, then your maximum heart rate is M  220  A Use this formula to complete the following tables.

27.

Age

Maximum Heart Rate

(years)

(beats per minute)

28.

Age

Maximum Heart Rate

(years)

(beats per minute)

18

15

19

20

20

25

21

30

22

35

23

40

Training Heart Rate A person’s training heart rate, in beats per minute, is the person’s resting heart rate plus 60% of the difference between maximum heart rate and his resting heart rate. If resting heart rate is R and maximum heart rate is M, then the formula that gives training heart rate is 3 T  R   (M  R ) 5 Use this formula along with the results of Problems 29 and 30 to fill in the following two tables.

29. For a 20-year-old person

Resting Heart Rate (beats per minute)

30. For a 40-year-old person

Training Heart Rate (beats per minute)

Resting Heart Rate (beats per minute)

60

60

65

65

70

70

75

75

80

80

85

85

Training Heart Rate (beats per minute)

B Use the rate equation d  r  t to solve Problems 31 and 32. [Example 5] 31. At 2:30 P.M. Shelly leaves her house and drives at an

32. At 1:30 P.M. Cary leaves his house and drives at an

average speed of 55 miles per hour to her sister’s

average speed of 65 miles per hour to his brother’s

house. She arrives at 6:30 P.M.

house. He arrives at 5:30 P.M.

a. How many hours was the drive to her sister’s

a. How many hours was the drive to his brother’s

house?

b. How many miles from her sister does Shelly live?

house?

b. How many miles from his brother’s house does Cary live?

576

Chapter 8 Solving Equations

d Use the rate equation r   to solve Problems 33 and 34. t

33. At 2:30 P.M. Brittney leaves her house and drives 260

34. At 8:30 A.M. Ethan leaves his house and drives 220

miles to her sister’s house. She arrives at 6:30 P.M.

miles to his brother’s house. He arrives at 12:30 P.M.

a. How many hours was the drive to her sister’s

a. How many hours was the drive to his brother’s

house?

house?

b. What was Brittney’s average speed?

b. What was Ethan’s average speed?

As you know, the volume V enclosed by a rectangular solid with length l, width w, and height h is V  l  w  h. In Problems 35-38, find V if:

35. l  6 inches, w  12 inches, and h  5 inches 1 2

36. l  16 inches, w  22 inches, and h  15 inches 5 2

1 3

37. l  6 yards, w   yard, and h   yard

5 3

38. l  30 yards, w   yards, and h   yards

Suppose y  3x  2. In Problems 39–44, find y if:

39. x  3

40. x  5

1 3

41. x   

2 3

42. x  

43. x  0

44. x  5

48. y  5

49. y  3

50. y  3

54. x  3

55. x  

56. x   

Suppose x  y  5. In Problems 45–50, find x if:

45. y  2

46. y  2

47. y  0

Suppose x  y  3. In Problems 51–56, find y if:

51. x  2

52. x  2

53. x  0

1 2

1 2

Suppose 4x  3y  12. In Problems 57–62, find y if:

57. x  3

58. x  5

1 4

60. x  

3 2

61. x  0

62. x  3

1 3

66. y  

5 3

67. y  0

68. y  3

59. x   

Suppose 4x  3y  12. In Problems 63-68, find x if:

63. y  4

64. y  4

65. y   

Find the complement and supplement of each angle. [Example 6]

69. 45°

70. 75°

71. 31°

72. 59°

8.6 Problem Set

577

Applying the Concepts 73. Digital Video The most popular video download of all

74. Vehicle Weight If you can measure the area that the tires

time was a Star Wars movie trailer. The video was com-

on your car contact the ground, and you know the air

pressed so it would be small enough for people to

pressure in the tires, then you can estimate the weight

download over the Internet. A formula for estimating

of your car, in pounds, with the following formula:

the size, in kilobytes, of a compressed video is height  width  fps  time S   35,000

W  APN where W is the vehicle’s weight in pounds, A is the average tire contact area with a hard surface in square

where height and width are in pixels, fps is the number

inches, P is the air pressure in the tires in pounds per

of frames per second the video is to play (television

square inch (psi, or lb/in2), and N is the number of

plays at 30 fps), and time is given in seconds.

tires.

a. Estimate the size in kilobytes of the Star Wars trailer that has a height of 480 pixels, has a width of 216 pixels, plays at 30 fps, and

Tire Pressure P Contact Area A

runs for 150 seconds.

b. Estimate the size in

a. What is the approximate weight of a car if the aver-

kilobytes of the Star

age tire contact area is a rectangle 6 inches by 5

Wars trailer that has a

inches and if the air pressure in the tires is 30 psi?

height of 320 pixels, has a width of 144 pix-

b. What is the approximate weight of a car if the aver-

els, plays at 15 fps, and

age tire contact area is a rectangle 5 inches by 4

runs for 150 seconds.

inches, and the tire pressure is 30 psi?

75. Temperature The chart shows the temperatures for some of the world’s hottest places.

76. Fermat’s Last Theorem The postage stamp shows Fermat’s last theorem, which states that if n is an integer greater than 2, then there are no positive integers x, y, and z

160

Heating Up

that will make the formula xn  yn  zn true.

140

137˚F Al’Aziziyah, Libya

120

134˚F Greenland Ranch, Death Valley, United States 100

131˚F Ghudamis, Libya 131˚F Kebili, Tunisia

80

130˚F Tombouctou, Mali 60

Source: Aneki.com

40

5

a. Use the formula C  9(F  32) to find the temperature in Celsius for Al’Aziziyah.

Use the formula xn  yn  zn to

a. Find x if n  1, y  7, and z  15. 5

b. Use the formula K  9(F  32)  273 to find the temperature in Ghudamis, Libya, in Kelvin.

b. Find y if n  1, x  23, and z  37.

578

Chapter 8 Solving Equations

Maintaining Your Skills Simplify. 3  5 77.  4  5

5  7 78.  6  7

1 1   2 79.  1 1   2

1 1   3 80.  1 1   3

1 1    2 4 81.  1 1    4 8

1 1    2 4 82.  1 1    4 8

3 3    5 7 83.  3 3    5 7

5 5    7 8 84.  5 5    7 8

Chapter 8 Summary Combining Similar Terms [8.1] EXAMPLES Two terms are similar terms if they have the same variable part. The expressions 7x and 2x are similar because the variable part in each is the same. Similar terms

1. 7x  2x  (7  2)x  9x

are combined by using the distributive property.

Finding the Value of an Algebraic Expression [8.1] An algebraic expression is a mathematical expression that contains numbers and variables. Expressions that contain a variable will take on different values depending on the value of the variable.

2. When x  5, the expression 2x  7 becomes 2(5)  7  10  7  17

The Solution to an Equation [8.2] A solution to an equation is a number that, when used in place of the variable, makes the equation a true statement.

The Addition Property of Equality [8.2] 3. We solve x  4  9 by adding 4

Let A, B, and C represent algebraic expressions. If then

AB ACBC

In words: Adding the same quantity to both sides of an equation will not change

to each side. x49 x4494 x  0  13 x  13

the solution.

The Multiplication Property of Equality [8.3] Let A, B, and C represent algebraic expressions, with C not equal to 0. If then

1 3

4. Solve x  5. 1 x  5 3

AB AC  BC

In words: Multiplying both sides of an equation by the same nonzero number will not change the solution to the equation. This property holds for division as well.

1 3  x  3  5 3 x  15

Steps Used to Solve a Linear Equation in One Variable [8.4] 5. 2(x  4)  5  11

Step 1 Simplify each side of the equation. Step 2 Use the addition property of equality to get all variable terms on one side and all constant terms on the other side.

2x  8  5  11 2x  3  11 2x  3  3  11  3 2x  8 2x 8    2 2 x  4

Chapter 8

Solving Equations

579

580

Chapter 8 Solving Equations

Step 3 Use the multiplication property of equality to get just one x isolated on either side of the equation.

Step 4 Check the solution in the original equation if necessary. If the original equation contains fractions, you can begin by multiplying each side by the LCD for all fractions in the equation.

Evaluating Formulas [8.6] w  8 and l  13 the formula P  2w  2l becomes P  2  8  2 13  16  26  42

6. When

In mathematics, a formula is an equation that contains more than one variable. For example, the formula for the perimeter of a rectangle is P  2l  2w. We evaluate a formula by substituting values for all but one of the variables and then solving the resulting equation for that variable.

Chapter 8

Review

Simplify the expressions by combining similar terms. [8.1]

1. 10x  7x

2. 8x  12x

3. 2a  9a  3  6

4. 4y  7y  8  10

5. 6x  x  4

6. 5a  a  4  3

7. 2a  6  8a  2

8. 12y  4  3y  9

Find the value of each expression when x is 4. [8.1]

9. 10x  2

10. 5x  12

11. 2x  9

13. Is x  3 a solution to 5x  2  17? [8.2]

12. x  8

14. Is x  4 a solution to 3x  2  2x  1? [8.2]

Solve the equations. [8.2, 8.3, 8.4]

15. x  5  4

16. x  3  2x  6  7

17. 2x  1  7

18. 3x  5  1

19. 2x  4  3x  5

20. 4x  8  2x  10

21. 3(x  2)  9

22. 4(x  3)  20

23. 3(2x  1)  4  7

24. 4(3x  1)  2(5x  2)

25. 5x    

27. Number Problem The sum of a number and 3 is 5.

3 8

1 4

7 x

2 5

26.     1

28. Number Problem If twice a number is added to 3, the re-

Find the number. [8.5]

sult is 7. Find the number. [8.5]

29. Number Problem Three times the sum of a number and 2

30. Number Problem If 7 is subtracted from twice a number,

is 6. Find the number. [8.5]

the result is 5. Find the number. [8.5]

31. Geometry The length of a rectangle is twice its width. If

32. Age Problem Patrick is 3 years older than Amy. In 5

the perimeter is 42 meters, find the length and the

years the sum of their ages will be 31. How old are they

width. [8.5]

now? [8.5]

In Problems 33-36, use the equation 3x  2y  6 to find y. [8.6]

33. x  2

34. x  6

1 3

36. x  

35. x  0

In Problems 37–39, use the equation 3x  2y  6 to find x when y has the given value. [8.6]

37. y  3

38. y  3

39. y  0

Chapter 8

Review

581

Chapter 8

Cumulative Review

Simplify.

1. 5,309  687

7 11

4 5

2.   

5. 2305(407)

6. 0.002(230)

7. 3141 3 ,1 8 8 

8.   

6 32

9. Round the number 435,906 to the nearest ten thou-

1 8

3. 11.09  6.531

3 4

4. 4  1

9 48

10. Write 0.48 as a fraction in lowest terms.

sand.

76 12

11. Change  to a mixed number in lowest terms.

2 5

12. Find the difference of 0.45 and .

13. Write the decimal 0.8 as a percent.

Use the table given in Chapter 6 to make the following conversion.

14. 7 kilograms to pounds

15. Write 124% as a fraction or mixed number in lowest

16. What percent of 60 is 21?

terms.

Simplify.

3 9 1

1

3

17.   

2

21. 19  5(7  4)

18. 8x  9  9x  14

3(8)  4(2) 11  9

19.  7

20. 

22. 25   16 

Solve. 3 8

23.  y  21

24. 3(2x  1)  3(x  5)

26. Write the following ratio as a fraction in lowest terms: 0.04 to 0.32

582

Chapter 8 Solving Equations

3.6 4

4.5 x

25.   

27. Subtract 3 from 5.

Chapter 8 28. Identify the property or properties used in the following: (6  8)  2  6  (8  2).

Cumulative Review

583

29. Surface Area Find the surface area of a rectangular solid with length 7 inches, width 3 inches, and height 2 inches.

30. Age Ben is 8 years older than Ryan. In 6 years the sum of their ages will be 38. How old are they now?

31. Gas Mileage A truck travels 432 miles on 27 gallons of gas. What is the rate of gas mileage in miles per gallon.

32. Discount A surfboard that usually sells for $400 is

33. Geometry Find the length of the hypotenuse of a right

marked down to $320. What is the discount? What is

triangle with sides of 5 and 12 meters.

the discount rate?

34. Cost of Coffee If coffee costs $6.40 per pound, how

35. Interest If $1,400 is invested at 6% simple interest for 90

much will 2 lb 4 oz, cost?

days, how much interest is earned?

36. Wildflower Seeds C.J. works in a nursery, and one of his tasks is filling packets of wildflower seeds. If each

37. Checking Account Balance Rosa has a balance of $469 in her checking account when she writes a check for $376

1

packet is to contain 4 pound of seeds, how many pack-

for her car payment. Then she writes another check for

ets can be filled from 16 pounds of seeds?

$138 for textbooks. Write a subtraction problem that gives the new balance in her checking account. What is the new balance?

38. Commission A car stereo salesperson receives a com-

39. Volume How many 8 fluid ounce glasses of water will it

mission of 8% on all units he sells. If his total sales for

take to fill a 15-gallon aquarium?

March are $9,800, how much money in commission will he make?

40. Internet Access Speed The table below gives the speed of the most common modems used for Internet access. The abbreviation bps stands for bits per second. Use the template to construct a bar chart of the information in the table. 900,000

MODEM SPEEDS 800,000

Modem Type

Speed (bps)

28K

28,000

56K

56,000

ISDN

128,000

Cable

512,000

DSL

786,000

Speed (bps)

700,000 600,000 500,000 400,000 300,000 200,000 100,000 0 28K

56K

ISDN

Modem type

Cable

DSL

Chapter 8

Test

Simplify each expression by combining similar terms.

1. 9x  3x  7  12

2. 4b  1  b  3

Find the value of each expression when x  3.

3. 3x  12

4. x  12

5. Is x  1 a solution to 4x  3  7?

6. Use the equation 4x  3y  12 to find y when x  3.

Solve each equation.

7. x  7  3

2 3

9.  y  18

8. a  2.9  7.8

7 x

1 6

10.     1

11. 3x  7  5x  1

12. 2(x  5)  8

13. 3(2x  3)  3(x  5)

14. 6(3x  2)  8  4x  6

15. Number Problem Twice the sum of a number and 3 is

16. Hot Air Balloon The first successful crossing of the At-

10. Find the number.

lantic in a hot air balloon was made in August 1978 by Maxie Anderson, Ben Abruzo, and Larry Newman of the United States. The 3,100 mile trip took approxid

mately 140 hours. Use the formula r  t to find their average speed to the nearest whole number.

17. Geometry The length of a rectangle is 4 centimeters

18. Age problem Karen is 5 years younger than Susan.

longer than its width. If the perimeter is 28 centimeters,

Three years ago, the sum of their ages was 11. How old

find the length and the width.

are they now?

584

Chapter 8 Solving Equations

Chapter 8 Projects SOLVING EQUATIONS

GROUP PROJECT The Equation Game Number of People Time Needed Equipment

2–5 30 minutes Per group: deck of cards, timer or clock, pencil and paper, copy of rules.

Background

The Equation Game is a fun way to practice working with equations.

Procedure

Remove all the face cards from the deck. Aces will be 1’s. The dealer deals four cards face up, a fifth card face down. Each player writes down the four numbers that are face up. Set the timer for 5 minutes, then flip the fifth card. Each player writes down equations that use the numbers on the first four cards to equal the number on the fifth card. When the five minutes are up, figure out the scores. An equation that uses 1 of the four cards scores 0 points 2 of the four cards scores 4 points 3 of the four cards scores 9 points 4 of the four cards scores 16 points Check the other players’ equations. If you find an error, you get 7 points. The person with the mistake gets no points for that equation.

Example

The first four cards are a four, a nine, an ace, and a two. The fifth card is a seven. Here are some equations you could make: One solution (9 points)

927 4217 9  (4  2) 1

7

*This project was adapted from www.exploratorium.edu/math_explorer/fantasticFour.html.

Chapter 8

Projects

585

RESEARCH PROJECT Algebraic Symbolism Algebra made a beginning as early as 1850 B.C. in Egypt. However, the symbols we use in algebra today took some time to develop. For example, the algebraic use of letters for numbers began much later with Diophantus, a mathematician famous for studying Diophantine equations. In the early centuries, the full words plus, minus, multiplied by, divided by, and equals were written out. Imagine how much more difficult your homework would be if you had to write out all these words instead of using symbols. Algebraists began to come up with a system of symbols to make writing algebra easier. At first, not everyone agreed on the symbols to be used. For example, the present division sign  was often used for subtraction. People in different countries used different symbols: the Italians preferred to use p and m for plus and minus, while the less traditional Germans were starting to use  and . Research the history of algebraic symbolism. Find out when the algebraic symbols we use today (such as letters to represent variables, , , a , , a/b and ) came into common use. Sumb marize your results in an essay.

586

Chapter 8 Solving Equations

Appendix A RESOURCES By gathering resources early in the term, before you need help, the information about these resources will be available to you when they are needed.

Instructor Knowing the contact information for your instructor is very important. You may already have this information from the course syllabus. It is a good idea to write it down again. Name Available

Office Location Hours: M

Phone Number

T ext.

W

TH

F

E-mail Address

@

Tutoring Center Many schools offer tutoring, free of charge to their students. If this is the case at your school, find out when and where tutoring is offered. Tutoring Location Available

Hours: M

Phone Number T

W

ext. TH

F

Computer Lab Many schools offer a computer lab where students can use the online resources and software available with their textbook. Other students using the same software and websites as you can be very helpful. Find out where the computer lab at your school is located. Computer Lab Location Available

Hours: M

Phone Number T

W

ext. TH

F

Videos A complete set of videos is available to your school. These videos feature the author of your textbook presenting fulllength, 15- to 20-minute lessons from every section of your textbook. If you miss class, or find yourself behind, these tapes will prove very useful. Videotape Location Available

Hours: M

Phone Number T

W

ext. TH

F

Classmates Form a study group and meet on a regular basis. When you meet try to speak to each other using proper mathematical language. That is, use the words that you see in the definition and property boxes in your textbook. Name

Phone

E-mail

Name

Phone

E-mail

Name

Phone

E-mail

587

Appendix B ONE HUNDRED ADDITION FACTS

The following 100 problems should be done mentally. You should be able to find these sums quickly and accurately. Do all 100 problems, and then check your answers. Make a list of each problem you missed, and then go over the list as many times as it takes to memorize the correct answers. Once this has been done, go back and work all 100 problems again. Repeat this process until you get all 100 problems correct. Add.

1.

0

2.

4

9.

9

10.

8

17.

5

5

18.

3

26.

0

34.

8

42.

3

50.

2

58.

3

66.

3

74.

6

82.

3 4

588

6

1

6

9

4

1

90.

4

43.

5 0

20.

7

1

7

51.

7

28.

2

36.

3

44.

9

52.

5

60.

99.

0

29.

5

8

0

6

68.

7

37.

1

45.

7

53.

92.

4 3

1

100. 4

6

2

1

2

7

8

61.

4

30.

8

38.

6

46.

0

54.

7 1

3

0

8

6

62.

6

31.

4

39.

2

47.

7

55.

0 9

1

5

8

9

63.

2

32.

8

40.

9

48.

2

56.

9 0

8 9

64.

7 9

72.

2 4

80.

9 1

88.

3

95.

6 7

2

87.

9 9

7

79.

7 6

0

71.

5 2

6

8

94.

24.

4

2

86.

6

6 4

9

4

78.

16.

7

1

70.

0

2 6

5

6

8

93.

23.

5

3

85.

1

8.

1

5

8

77.

15.

1

8

69.

1

5 6

0

3

7

6

22.

3

2

84.

5

7.

4

8

2

76.

14.

5

0

5

91.

4

4

2 5

1

1

7

83.

21.

2

8

75.

0

6.

5

4

1

67.

13.

6

5

59.

9

4 1

7

4

0

98.

5

5.

4

8

1

8

97.

35.

7

5

89.

8

12.

0

3

2

81.

27.

2

9

73.

3

3

0 3

8

3

0

65.

19.

9

1

57.

9

4.

7

0

0

49.

11.

6

3

41.

4

2 7

5

7

33.

3.

9

3

25.

1 9

3 9

96.

8 6

Appendix C ONE HUNDRED MULTIPLICATION FACTS The following 100 problems should be done mentally. You should be able to find these products quickly and accurately. Do all 100 problems, and then check your answers. Make a list of each problem you missed, and then go over the list as many times as it takes to memorize the correct answers. Once this has been done, go back and work all 100 problems again. Repeat this process until you get all 100 problems correct. Multiply.

1.

3

2.

4

9.

7

10.

1

17.

5

2

18.

0

26.

4

34.

1

42.

9

50.

9

58.

6

66.

0

74.

9

82.

4 3

8

9

2

6

5

3

90.

8

43.

1 6

20.

1

2

3

51.

2

28.

9

36.

3

44.

9

52.

1

60.

99.

4

29.

5

9

8

7

68.

1

37.

6

45.

8

53.

92.

8 3

6

100. 1

7

0

3

1

3

5

61.

6

30.

9

38.

7

46.

9

54.

7 5

6

2

8

7

62.

0

31.

1

39.

4

47.

7

55.

2 1

5

0

7

1

63.

9

32.

4

40.

7

48.

8

56.

6 6

0 2

64.

8 9

72.

2 2

80.

5 0

88.

4

95.

1 9

6

87.

6 2

1

79.

7 3

3

71.

0 9

4

4

94.

24.

9

0

86.

5

3 7

7

2

78.

16.

4

1

70.

8

7 2

7

8

0

93.

23.

3

0

85.

8

8.

1

8

6

77.

15.

8

5

69.

4

4 4

2

2

6

2

22.

4

9

84.

4

7.

5

9

5

76.

14.

8

7

1

91.

4

3

1 7

6

7

2

83.

21.

6

1

75.

0

6.

5

6

5

67.

13.

7

4

59.

5

2 5

4

0

5

98.

6

5.

3

9

9

1

97.

35.

1

0

89.

4

12.

8

4

3

81.

27.

3

7

73.

6

2

0 6

0

9

8

65.

19.

0

3

57.

0

4.

6

8

9

49.

11.

1

8

41.

5

0 5

3

7

33.

3.

9

8

25.

5 4

2 0

96.

3 2

589

This page intentionally left blank

Solutions to Selected Practice Problems Solutions to all practice problems that require more than one step are shown here. Before you look back here to see where you have made a mistake, you should try the problem you are working on twice. If you do not get the correct answer the second time you work the problem, then the solution here should show you where you went wrong.

Chapter 1 Section 1.2 1.

2.

63

342

3. a.

1

b.

375

22

11 1 1

11 23

49 5

4. a. 57,90 4

b. 68,4 95

25

605

121

699

7,193

7,236

88

947

473

 978

655

878

969

2,172

65,752

29 5 76,643

8. a. n  8, since 8  9  17 b. n  8, since 8  2  10

7. a. 6  2  4  8  3  (6  4)  (2  8)  3  10  10  3  23 b. 24  17  36  13  (24  36)  (17  13)  60  30  90

c. n  1, since 8  1  9 9. a. 7  7  7  7  28 ft b. 88  88  33  33  242 in. c. 44  66  77  187 yd

d. n  6, since 16  6  10

Section 1.3 b. Savings $2,149

5. a. Food $ 5,296 Car

Taxes

4,847

Total

Total $10,143  $10,140 to the nearest ten dollars

6,137 $8,286  $8,300 to the nearest hundred dollars

c. House $10,200 Taxes

6,137

Misc.

6,142

Car

4,847

Savings Total

2,149 $29,475  $29,000 to the nearest thousand dollars

6. a. We round each of the four numbers in the sum to the nearest thousand, and then we add the rounded numbers. 5,287

rounds to

2,561

rounds to

5,000 3,000

888

rounds to

1,000

4,898

rounds to

 5,000 14,000

We estimate the answer to this problem to be approximately 14,000. The actual answer, found by adding the original, unrounded numbers, is 13,634.

b. We round each of the four numbers in the sum to the nearest thousand, and then we add the rounded numbers. 702

rounds to

2,944

rounds to

1,000 4,000

1,001

rounds to

1,000

3,500

rounds to

 4,000 10,000

We estimate the answer to this problem to be approximately 10,000. The actual answer, found by adding the original, unrounded numbers, is 9,147.

Section 1.4 1. a.

3. a.

b.

b.

345

7,406

2. a. 6,857

 431

3,405

 405

 234

253

4,001

6,452

111

684

63  6 tens  3 ones  5 tens  13 ones 47  4 tens Answer: 16

7 ones  4 tens

7 ones

1 ten  6 ones

b.

532  5 hundreds  3 tens  2 ones  5 hundreds  2 tens  12 ones 403  4 hundreds Answer: 129

0 tens

3 tens  4 hundreds

0 tens

3 ones

1 hundred  2 tens  9 ones

Solutions to Selected Practice Problems

S-1

S-2

Solutions to Selected Practice Problems 5 15

2 16

4. a.  6 6 5

b. , 3 72 1 9

283

1,749

373

1,980

Section 1.5

4. a.

 28,000

 2,800

 280

5

c. 4  7,000  7,000  7,000  7,000 7,000

b. 4  700  700  700  700 700

1. a. 4  70  70  70  70  70 57

5

b.

5. a.

570

 8

 8

456

4,560

45

1

b.

6 20

62

45

90 m8 2(45)  90

3,100 m8 5(620)  3,100

2,700 m8 60(45)  2,700

24,800 m8 40(620)  24,800

2,790

6. a.

b.

356

27,900

7.

3,560

365

641

641

 550

356 m8 1(356)  356

3,560 m8 1(3,560)  3,560

18,250

14,240 m8 40(356)  14,240

142,200 m8 40(3,560)  142,400

182,500

213,600 m8 600(356)  213,600

2,136,000 m8 600(3,560)  2,136,000

228,196

2,281,960

200,750 mg

8. 36($12)  $432 Total weekly earnings $432  $109  $323

Take-home pay

9. Fat: 3(10)  30 grams of fat; sodium: 3(160)  480 milligrams

10. Bowling for 3 hours burns 3(265)  795 calories. Eating two bags of chips means you are consuming 2(3)(160)  960 calo-

of sodium

ries. No; bowling won’t burn all the calories.

Section 1.6

m8 m88888888

m8

283

2 8  16

28 16 16

1 92

72  00

11

72  0

5.

104 R 11, or 1041 8

156

The family spent $156 per day

121 ,8 7 2 

181 ,8 8 3 

m8 m88888888

m8

b.

0  72

m8 m88888888

20

1 8 07

19 2  72

72 0

69 R 20, or 6927 271 ,8 8 3  1 62 263 243 20

208 91 ,8 7 2 

48  19 9

1 99

72

4. a.

3.

2,830 246 7 ,9 2 0 

48

16  00

0

b.

,7 9 2  246

m8 m88888888

2. a.

740 42 ,9 6 0 

m8 m88888888 m888888888888888

b.

74 42 9 6 

m8 m88888888

1. a.

12

1 8  08

67 60

0  83

72 72

72  11

0

Section 1.7 1. Base 5, exponent 2; 5 to the second power, or 5 squared

2. Base 2, exponent 3; 2 to the third power, or 2 cubed

3. Base 1, exponent 4; 1 to the fourth power 4. 52  5  5  25 4 5 7. 1  1  1  1  1  1 8. 2  2  2  2  2  2  32 9. 71  7 13. a. 5  7  3  6  35  18  17

b. 5  70  3  60  350  180

5. 92  9  9  81 6. 23  2  2  2  8 1 0 10. 4  4 11. 9  1 12. 10  1

14. 7  3(6  4)  7  3(10)

 170

 7  30  37

15. a. 28  7  3  4  3 1

b. 6  32  64  24  2  6  9  64  16  2  54  4  2  58  2  56

Solutions to Selected Practice Problems 16. a. 5  3[24  5(6  2)]  5  3[24  5(4)]

b. 50  30[240  50(6  2)]  50  30[240  50(4)]

 5  3[24  20]

 50  30[240  200]

 5  3[4]

 50  30(40)

 5  12

 50  1,200

 17

17.

S-3

 1,250

18. First we place them in order from smallest to largest

187 273

150 173 187 227 273

1010   202 miles 5

150 173

Because there are 5 numbers, the one in the middle, 187, is the median.

227 1010

19. The numbers are already in order from smallest to largest. Be-

20. The most frequently occurring score is 74. It occurs three

cause there is an even number of numbers, we find the mean

times. The mode is 74.

of the middle two: 42,635  44,475 87,110     43,555 2 2 The median is $43,555.

4. V  15  12  8  1,440 ft3

Section 1.8

5. a. Surface area  2(15  8)  2(8  12)  (15  12)  612 ft2

1. A  bh  3  2  6 cm2

b. Two gallons will cover it, with some paint left over.

2. A  l w  70  35  2,450 mm2 3. A  38  13  24  27  494

 648

 1142 ft2

Chapter 2 Section 2.1 24 34

2 3

2  4x 3  4x

2 3

8 12

6.     

8x 12x

15  5 20  5

15 20

7.     

3 4

1 3

8.     

4 4

4 1 12 6

2 2

2 1 12 4

3 3

3 12

10.     ;     ;     

Section 2.2 1. 37 and 59 are prime numbers; 39 is divisible by 3 and 13; 51 is divisible by 3 and 17. 2. a. 90  9  10 n 88 88n 8n 88n

 3  3  25  4 335522

 2  32  5

 22  32  52

1 5 25 5

1 10

8.     

300 350

5 23 2 5  2 5 57

6 7

b.      120 25

12  6 18  6

2 3

4.     

3325 23 5 30 6 6. a.      35 7 7 5 5 50

12 18

b. 900  9  100

2223 5 5 5

8 72

15 20

3 5 22 5

3 4

5.     

 2 2 21  2 2 233

1 9

7. a.     

16 144

2  2 2 2 2 2 2 2 33

1 9

b.     

24 5

9.     

Section 2.3 2 3

5 9

10 27

2 5

1.     

2 5

7 1

2.   7    



1 4 3 5

1 3

14   5 12 25

5 6

12  5 25  6

4. a.     



 

1 4 3 15

3.        4   45

12 25

50 60

12  50 25  60

b.     

8 3

9 24

89 3  24

5. a.     

8 30

90 24

8  90 30  24

b.     

2 5 (2   3)     ( 5  5)  (2 3 )

(2 2 3 )  (2  5 5 )   ( 55 )  (2 2 3   5)

(2  2 2)  (3 3 )   2   (2 3 2  3)

 2 2)  (2  3 3 5) (2   (2  3 5)  (2  2 2 3)

2   5

2   5

1   1

1   1

1

1

S-4

Solutions to Selected Practice Problems

3 4

8 3

381 436

1 6

6.          2)  1 3  (2 2   2)  3 (2    (2   3) 1   3

3 2

7. 

2

4

2 2     3 3

3

2

8. a. 

1 3 3 1         2 4 4 2

4   9

2

3

b. 

3

9 2 2 2 9           8 3 3 3 8

2 3

21  3 2

1 2

2229   3338

9   32

3 5

9. a.     

3 15 5 1

 

b. (15)   

33 5    5 9   1

1   3

2  2  2  (3  3)   3  3  3  (2  2  2)

9

 2 2  (3  3) 2   33  3  (2  2 2) 1   3 2 12 3 1

 

2 3

2 120 3 1



2 3

10. a. (12)   

b. (120)   



1 2

11. A  (7)(10)

222 3    31

2222 35    3

8   1

80   1

8

 80

12.

A = 4 × 4 = 16 ft 2 4 ft

 35 in2 1 A= – ×2×2 2 = 2 ft 2

4 ft 6 ft

10 ft A= 8 × 2 = 16 ft 2

Total area  2  16  16  34 ft2

`

Section 2.4 1 3

1 6

1 3

1 30

6 1

1. a.       

1 60

1 30

60 1

b.       

5 9

10 3

5 9

3 4

3 10

2.       

3 4

3 5

1 3

3. a.   3    

6   3

12235   2351

 5 3   32 3 5

2

2   1

1   6

3 5

1 3

b.   3    

3 7

3 7

1   5

1   4

1   7

2

5 1

10 42

5 32

4. 4    4(5)

15 32

42 10 5   (2   3  7)   22222 2 5 5 32

5. a.       

 20

30 42

15 32

42 30 (3  5)  (2   3  7)   (2   2  2  2  2)  (2   3 5)

b.       

21   32 12 25

24 25

5 4

1 8

21   32

2 2 31   3 552 

24 1 25 6  1 2223   (5  5)  (2  3)

2   25

4   25

12 25

1 6

6.   6    

5 4

b.   6    

8 1

8.     8      8  10  8  18

5 3

2

3 4

3

4 5

9 25

2

4 25

9. 18    48    18    48   25 25  18    48   9 4  50  300  350

5

4

b. 12    12 

9

5 2

4

7. a. 12    12 

 15

3 4

4 3

10. 12    12   44  16 blankets

1 3

c.   3    

4 7

7

4

c. 12    12   21

Solutions to Selected Practice Problems

S-5

Section 2.5 3 10

31 10

1 10

1.     

a5 12

a53 12

3 12

8 7

2.      a8   12

4   10

85 7

5 7

5 9

3.     

8 9

3   7

18   9 2

2   5

5. a.

18  2  3  3



14  2  7

2 9

LCD  2  3  3  7

25 95

4 15

b.

 126 43 15  3

2 27

8. a.       

4 45

36  2  2  3  3 28  2  2  7

25 27  5



LCD  2  2  3  3  7  252

43 45  3

8 25

b.       

84 25  4

3 20

35 20  5

9. LCD  100;       

10 12     45 45

10 12     135 135

32 15     100 100

22   45

22   135

17   100

3 4

1 5

35 45

14 54

1 9

10. LCD  20;       

3 4

585 9

5 9

4.       

2 1

1 4

14 94

1 6

19 49

16 66

11. a. LCD  36;           

1 90

1 40

1 60

4 9 6       36 36 36

4 9 6       360 360 360

11   20

19   36

19   360

3 4

24 3     14 4 8 3      4 4 5   4

Section 2.6 2 3

2 3

6.

1 6

1 6

2 3

2. 3  3   3 1     1 6

53 2     13 3

36 1     16 6

15 2     3 3

18 1     6 6

17   3

19   6

4

7.

(3  5)  2 3

3. 5  

5 2     1 3

2 14 4 4  so   2 51 5 5 10

4 9

3

(9  6)  4 9

17   3

9 2

58   9

7 207 25 0 7  so   7 262 26 26 182

Section 2.7 3 4

1 3

11 4

13 3

5 8

2 1

29 8

2. 2  3    

3 5

2 5

8 5

17 5

3. 1  3    

5 8

37 8

2 1

4. 4  2    

143   12

58   8

8 5     5 17

37 1     8 2

11  11 12

2  7 8

8   17

37   16

1  7 4

11 3

2 3

1  so   3 5. 31

4. 6  

25

1. 2  4    

19 40  9

15 4     20 20

12. 2      

1. 5  5  

14 90  4

5  2 16

16 60  6

b.           

S-6

Solutions to Selected Practice Problems

Section 2.8 2 3

1 4

2 3

1 4

1. 3  2  3    2  

3 35 15 5  5  5 4 45 20

2.

4 44 16  6  6  6 5 54 20



 24 13  5     34 43 8 3  5     12 12 2 1  (3  2)     3 4

3 32 6 6  6  6 4 42 8

3.

7 7  2  2 8 8

7  2 8

31 11 11 11  11  1  12 20 20 20

13 5 8  9 8 8

11 11  5    5 12 12

4.

1 14 4 2  2  2 3 34 12

5. 4

1 13 3 1  1  1 4 43 12

5 1 8

7 8

11 11 11  3  3  3 12 12 12

7 12  10

6.



7 7 12  12 10 10

10 

7.

7 9 7

2 22 4 7   7   7 5 52 10

4 4  5  5 7 7

3 5 10

3 4 7

2 1 3  3 8 4

18 1 6 6  7  7 12 2 12

8.





1 3 1 4 6  5      5 3 3 3 3 2 2  3

33 6  43

3 6  4

9.

9 21 6  5 12 12

2 2 2  2 3 3

5 52 10 10 2  2  2  2 6 62 12 12

2 3 3

11 3 12

Section 2.9

 2  4  1

 2  4 

3

3

11

1. 4  1 2  4   

3 2

1 6



33  4   8

2  3 2 5 4.      5 3 9  9 2 9     3 5

5 6

1 3

  6  6  5 25   6 6 5

1

2.    2  1   4

3 7

1 3



1 2

1 2



2

3 7

1 3

3.    1  4    (6)2 3 1    (36) 7 3

32 33     8 8

125   36

3    12 7

65   8

17  3 36

3  12 7

1  8 8 1 3 1 3    12    2 4 2 4 5.    2 1 2 1    12    3 4 3 4

 

 

2 2 4   12 4   3 3 6.    1 1 3   12 3   4 4

 

 

1 12 3 1 2 7.   12  6 2 3 3 6 3 37 20     3 3

18   15

1 3 12    12   2 4   2 1 12    12   3 4

2 12  4  12   3   1 12  3  12   4

6 1    1 5 5

69   83

48  8   36  3

37   20

15    3 5

56 23    1 33 33

17  1 20

37 3     3 20

Chapter 3 Section 3.1

4 10

6 100

2 1,000

1. 700  80  5      

2. a. Six hundredths b. Seven tenths c. Eight thousandths

3. a. Five and six hundredths b. Four and seven tenths c. Three and eight thousandths 4. a. Five and ninety-eight hundredths b. Five and ninety-eight thousandths 5. Three hundred five and four hundred six thousandths

S-7

Solutions to Selected Practice Problems

Section 3.2

45 38.45  38 100

1.

450  38 1,000

45 45 38.045  38  38 1,000 1,000

b.

6.

b.

6.70 4.65

4.6437

0.033 4.600  0.080

7.000

20.713

10.567

3.567 and  5.890 10.567

4.677

1 quarter  2 dimes  4 pennies  0.25  0.20  0.04  0.49, which is too much change.

$10.00 

5.

6.7000 2.0563

16.000

55.243

775 494  494.775 1,000

523 494  494.523 1,000

2.05

3.

78.674 23.431

730 73 456.73  456  456 1,000 1,000

73 73 456.073  456  456 1,000 1,000

4. a.

2.

9.56 One of the dimes should be a nickel. Tell the clerk that you have been given too much change. $

.44

7. a. P  1.38  1.38  1.38  1.38  5.52 in. b. P  6.6  4.7  4.7  16.0 cm

Section 3.3

4 10

4 100

6 10

1. a. 0.4  0.6    

6 100

b. 0.04  0.06    

5 10

5 100

7 1,000

2. a. 0.5  0.007    

7 100

b. 0.05  0.07    

24   100

24   10,000

35   10,000

35   10,000

 0.24

 0.0024

 0.0035

 0.0035

5 10

35 4 b. 0.35  0.4     100 10

4 100

3. a. 3.5  0.04  3   35 4     10 100

140   1,000

140   1,000

14   100

14   100

 0.14

4. a. 3  2  5 digits to the right

b. 2  4  6 digits to the right

 0.14

5. a.

b.

4.03

6. a. 80  6  480

40.3

5.22

0.522

806

806

8060

8060

201500

201500

21.0366

21.0366

7. a. 0.03(5.5  0.02)  0.03(5.52)

b. 40  180  7,200

8. a. 5.7  14(2.4)2  5.7  14(5.76)

b. 0.57  1.4(2.4)2  0.57  1.4(5.76)

 5.7  80.64

 0.57  8.064

 86.34

 8.634

10. 6.82(36)  10.23(14)  245.52  143.22

11. C  3.14(3)

 $388.74

b. A  lw  (39.6)(25.1)  993.96 mm2 12. a. C  ␲d (3.14)(0.92) 2.89 in. b. C  2␲r 2(3.14)(13.20) 82.90 mm

 9.42 cm

1 13. Radius  (20)  10 ft 2

14. Radius  2(0.125)  0.250 V  ␲r 2h

A  ␲r  (3.14)(10) 2

2

 (3.14)(0.250)2(6)

 314 ft2

 1.178 in3

Section 3.4

35

1 50

35

126 120

0

6.9

c.

7.1

53 4 .5 

53 5 .5 

30  45

35  05

45  0

5  0

3. a.

2.636 184 7 .4 4 8  36

11 4 10 8

64

54

60

108

60

108

0

0

b.

26.36 184 7 4 .4 8  m8

30

1 62

b.

m8 m88888888 m88888888888888

6.7 53 3 .5 

m8

m8 m88888888 m88888888888888

30

2. a.

m8

154.2 304 ,6 2 6 .0 

 0.01656

c. 82  64

9. a. A  s 2  1.382  1.90 in2

1.

b. 0.03(0.55  0.002)  0.03(0.552)

 0.1656

36  114

108  64 5 4  1 08 1 08  0

Solutions to Selected Practice Problems

4. a.

45.54 1 00

138 125

251 1 3 .8 5 0 

4.2.1 3 .2 .3 0 

100  13 8

126

12 5

1 00 1 00 0

2 10

100  0

0

1.422 0.32.0 .4 5 .5 3 0 

12 6  63

hundredth is 1.42

13 5 12 8

73

21 0  0

2 10

Answer to nearest

32

42  21 0

42

1 25  100

6.

0.42.1 3 .2 3 .0 

63

12 5  1 35

13 5

31.5

b.

3.15

m8 m88888888

m8 m88888888 m88888888888888

,1 3 8 .5 0  251

5. a.

m8

4.554

b.

m88888 m88888888888 m88888888888888888

S-8

64

90 64 26

7. a.

0.06.1 .9 0 .0 0 

Answer to nearest

8.

31.66

b.

3 16.66 0.06.1 9 .0 0 .0 0 

28.5 hours 6.54.1 8 6 .3 9 .0 

Answer to nearest tenth is 31.7

m8 m88888888

m8 m88888888 m88888888888888 m888888888888888888888

tenth is 316.7

130 8

18

18

10

10

55 59

6

6

52 32

40

40

3 27 0

36

36

3 27 0

40

40

36

36

0

4

40 36 4 4.39  0.43 3.96 9.     0.33

10.

0.33

Class

 12 additional minutes The call was 13 minutes long.

Algebra Chemistry English History

units

grade

value

5 4 3 3

B B A B

3 3 4 3

Total Units: 15

.4 .0  52

2. a.

2 so   0.4 5

b.

3 0.6 so   0.6 5 53 .0 

20

30

0

0

.8

c. 54 .0  40  0

11 0.9166 so   0.917 to the nearest thousandth 12 121 1 .0 0 0 0  m8 m88888888 m88888888888888

1. a.

10 8

20

12

80

72

80 72 8

5  3  15 4  3  12 3  4  12 33 9

48 GPA    3.20 15

Total Grade Points: 48

4 so   0.8 5

.9230

12 13

b. 131 2 .0 0 0 0  so   0.923 to the nearest thousandth m8

Section 3.5

grade points

11 7  30

26  40 39  10 0  10

Solutions to Selected Practice Problems 5 0.4545 so   0.4 5  11 .0 0 0 0  115

48 1,000

12 25

48 100

4. a. 0.48    

6 125

b. 0.048    

m8 m88888888 m88888888888888

3.

44

60 55

50

44

60 55 5 25 1,000

1 40

8 10

5. 0.025    

4 5

14 25

6. 12.8  12  12

7. (2.43  0.27)  0.56(2.43  0.27)  0.56(2.70)  1.512

5

1 4

3

 

1 4

1 3 4 5

8.   0.25      

3 1

5 1

3

9.  (5.4)  

2

1 1 (2.5)  (5.4)  (2.5) 27 25

1 3     4 20

1 4

3 4

10. 35.50  (35.50)  (35.50)  26.625

 0.2  0.1

 $26.63 to the nearest cent

 0.3

5 3     20 20 8   20 2   or 0.4 5 1 2

1 2

1 2

11. A   bh   (6.6)(3.3)  10.89 cm2

4 3

12. V  ␲r 2h     ␲r 3 1 4  (3.14)(10)2(10)     (3.14)(10)3 2 3 2  3,140   (3,140) 3  3,140  2,093.3  5,233.3 in3

Section 3.6 1. 425 45

2. 36   4 62

 20

6.

9.

    121 11 64

8

8

3.

    100 10 36

6

4. 1436   14  6

3   5

7. 514  5(3.7416574)

5. 81   25 95

 84

4

8. 405   147  20.124612  12.124356

 18.708287

 32.248968

 18.7083 to the nearest ten thousandth

 32.25 to the nearest hundredth

 0.583 3333   12 7

2 10. a. c  5   52

0.7637626

 25 25 

 0.764 to the nearest thousandth

 50  c  7.07 ft (to the nearest hundredth)

2 11. c  12   52  144   25

 169   13 ft

2 b. c  16   122

 256   144  400  c  20 cm

S-9

S-10

Solutions to Selected Practice Problems

Chapter 4 Section 4.1 3.2 2 b.    4.8 3

32 2 1. a.    48 3 0.06 0.12

3  5 3 10 2 2. a.        9 5 9 3  10 1 600 12 3 b.    4.    2 16 4 1,200

0.32 2 c.    0.48 3

0.06  100 0.12  100

6 12

4 12

1 3

1 2

3. a.       

12 4

0.6 0.9

2 3

b.   

3 1

12 16

3 4

5. Alcohol to water:    ; water to alcohol:    ; water to total solution:   

Section 4.2 107 miles 2 hours

192 miles 6 gallons

1.   53.5 miles/hour 48¢ 5.5 ounces

2.   32 miles/gallon

75 ¢ 11.5 ounces

219¢ 46 ounces

3.   8.7¢/ounce;   6.5¢/ounce;   4.8¢/ounce (Answers are rounded to the nearest tenth.)

Section 4.3 n 8  8

1.   n

y 3  3

2.   y

n 8  8

40 8

a 7  7

35 7

3.   

4.   

n5

5a

Section 4.4 1. First term  2, second term  3, third term  6, fourth term  9, means: 3 and 6; extremes: 2 and 9 2 10 3 3 5 10   2   3 3

2. a. 5  18  90 b. 13  3  39 6  15  90

3. a. 3  x  4  9

c.   5  

39  1  39

b. 5  x  8  3

d. 0.12(3)  0.36 0.18(2)  0.36

4. 2  19  8  y

3  x  36

5  x  24

x 3 36     3 3

5x  24    5  5

38 y 8    8  8

7.   

67x

x  4.8 3 5 6x9

6 x 7    7  7 6   x 7

x 6 9     6  6 3 x   2

x  12 3 4

6. a.   8  7  x

b. 6  x    15

5. a. 15  n  6(0.3)

38  8  y

b. 0.35(100)  n  7

15  n  1.8

35  n  7

n 15 1.8     15 15

35 n 7    7 7 

4.75  y 0.5 b 1 18 b  1  18(0.5)

n  0.12

5n

b9

Section 4.5 x 10

288 6

1. a.   

b.

2. a.

10 x    18 54

b.

x 10    27 18

x  6  10  288

x  6  11  288

x  18  54  10

x  6  2,880

x  6  3,168

x  18  540

x  18  270

x 6 2,880     6 6 

3,168 x 6    6  6

x  18  540     1 8 18 

270 x  18     1 8  18

x  480 miles

3.

x 288    11 6

x 8    35 20 x  20  35  8 x  20  280

x  528 miles

4.

105 x    1 4.75 x  1  4.75(105) x  498.75 miles

x  20  280     2 0 20 x  14 milliliters of alcohol

x  30 hits

x  18  27  10

x  15 hits

S-11

Solutions to Selected Practice Problems

Section 4.6 25 10

x 14

h 120

1.   

360 160

2.    9 h    reduce to lowest terms 120 4

10x  350 x  35

4h  1080 h  270 pixels

x 18

3. We see AC has a length of 3 units and BC has a length of 4 units. Since AC is proportional

4.   

42 12

5.   

12x  756

24b  480

to GI, which has a length of 9 units, we set up a proportion to find the length of a new side, HI. GI HI    BC AC

b 15

x  63 ft

9 HI    4 3

32 24

b  20 in.

HI  3 4 HI  12 Now we can draw HI with length 12 units, and complete the triangle by drawing line GH H

G

H

I

G

I

Chapter 5 Section 5.1 82 100

41 50

21.   

6.5 100

65 1000

1 42 2 100

13 200

5 8 3 27. a. 3  3.75  375% 4

25. a.   0.625  62.5%

85  2 100

9 10

23.   

22.     

9 8 7 b. 3  3.875  387.5% 8

b.   1.125  112.5%

24. a.   0.9  90%

85 1     2 100 85   200 17   40 7 1 26. a.   0.583   58% or 58.3% 12 3

9 20

b.   0.45  45%

13 12

1 3

b.   1.083   108% or 108.3%

Section 5.2 1. a. n  0.25(74)

b. n  0.50(74)

 18.5

4. n  0.635(45) n 28.6

5. n  85  11.9

25 n    100 74

n  50%

50  74  100  n

1850  100  n

3,700  100  n

9. a.

0.  40  n 35    0 .40 0.40  87.5  n

70  0.40  n

b.

70 0.  40  n    0 .40 0.40  175  n

7. 25 is what percent of 160? 25  n  160 25   n 160

159.0 n

n  14% 50 n    100 74

37  n

n  0.50

n  25% 0.  39  n 62     0 .39 0.39 

25  74  100  n 18.5  n

n  0.25

35  0.40  n

3. a.

42 n  84     8 4  84

62  0.39  n

6.

n  85  11.9     8 5 85 

b.

b. n  84  42

n  84  21    8 4 84 

 37

n  0.14

8. a.

2. a. n  84  21

21 n    84 100

n  0.156  15.6% to the nearest tenth of a percent 35 40 42 n b. 10. a.    b.    n 100 84 100

70 40    n 100

84  n  21  100

84  n  42  100

40  n  35  100

40  n  70  100

84  n  2100

84  n  4,200

40  n  3500

40  n  7,000

n  25 25%

n  50 50%

n  87.5

n  175

S-12

Solutions to Selected Practice Problems

Section 5.3 1. 114 is what percent of 150?

2. What is 75% of 40?

114  n  150 114 n 150    150 1 50 

3. 3,360 is 42% of what number?

n  0.75(40)

3,360  0.42  n

n  30 milliliters HCl

3,360 0.  42  n     0.42 0 .42 

n  0.76

4. What is 35% of 300? n  0.35(300)  105 students

n  8,000 students

n  76%

Section 5.4 1. What is 6% of $625? n  0.06(625)

2. $4.35 is 3% of what number?

3. $11.82 is what percent of $197?

4.35  0.03  n

n  $37.50

11.82  n  197

n  $145 Purchase price

4. What is 3% of $115,000? n  0.03(115,000)

n  0.06  6%

n  $3,450

Total price  $145  $4.35  $149.35

5. 10% of what number is $115?

6. $105 is what percent of $750?

0.10  n  115

105  n  750

n  $1,150

n  0.14  14%

Section 5.5 1. 0.07(18,000)  1,260

2. 0.89(271,000)  241,190

$18,000 Old salary  1,260 Raise

$7 is what percent of $35?

241,190 Increase

7  n  35

512,190  512,000 to the nearest thousand

$19,260 New salary

4. What is 15% of $550?

3. $35  $28  $7 Decrease

271,000 Drunk drivers in 1986

5. What is 15% of $45?

n  0.20  20% Decrease

What is 5% of $38.25?

n  0.15(550)

n  0.15(45)

n  0.05(38.25)

n  $82.50 Discount

n  $6.75 Discount

n  $1.91 to the nearest cent

$550.00 Original price 

82.50 Less discount

$45.00 Original price  6.75 Less discount

$467.50 Sale price

$38.25 Sale price  1.91 Sales tax

$38.25 Sale price

$40.16 Total price

Section 5.6 1. Interest  0.08($3,000)

2. Interest  0.12($7,500)

 $240 $3,000 Principal  240 Interest $3,240 Amount after 1 year

3. I  P  R  T

 $900 $7,500 Principal  900 Interest $8,400 Total amount to pay back

90 I  700  0.04   360

4. I  P  R  T

120 I  1,200  0.095   360

1 I  700  0.04   4

1 I  1,200  0.095   3

I  $7 Interest

I  $38 Interest $1,200 Principal 

38 Interest

$1,238 Total amount withdrawn

5. Interest after 1 year is

Interest paid the second year is

0.06($5,000)  $300 Total in account after 1 year is $5,000 Principal 

300 Interest

$5,300

0.06 ($5,300)  $318 Total in account after 2 years is $5,300 Principal 

318 Interest

$5,618

6. Interest at the end of first quarter

Interest for the third quarter

1 I  $20,000  0.08    $400 4

1 I  $20,808  0.08    $416.16 4

Total in account at end of first quarter

Total in account at the end of third quarter

$20,000  $400  $20,400 Interest for the second quarter

$20,808  $416.16  $21,224.16 Interest for the fourth quarter

1 I  $20,400  0.08    $408 4 Total in account at end of second quarter $20,400  $408  $20,808

1 I  $21,224.16  0.08    $424.48 to the nearest cent 4 Total in account at end of 1 year $21,224.16 

424.48

$21,648.64

Solutions to Selected Practice Problems

Section 5.7 1. a. 9  11  16  10  46

2. a. 0.76(600)  456 people b. 0.24(600)  144 people

3.

4.

Publisher 50%

Free Space 60%

Bookstore 45%

Used Space 40%

Author 5%

Chapter 6 Section 6.1 1. 8 ft  8  12 in.

t 1 yd

1 yd 3 ft

26   yd 3

 96 in.

2  8 yd, or 8.67 yd 3 1 m 10 dm 5. 78.4 mm  78.4  mm     1,000 mm 

7.

 1m

12 in. 1 ft

3f 3. 220 yd  220  yd    

2. 26 ft  26  ft  

1m 4. 67 cm  67  cm  

 220  3  12 in.

67 m   100

 7,920 in.

 0.67 m

28 feet of fencing 1.72 dollars 6. 6 pens  6 pens      1 pen

78.4  10   dm 1,000

 6  28  1.72 dollars

 0.784 dm

 $288.96

1 foot of fencing

1,100 f eet 60 minutes 1 mile 1,100 feet per minute       1 minute 5,280 f 1 hour eet 1,100  60 miles   5,280 hours  12.5 miles per hour, which is a reasonable speed for a chair lift.

Section 6.2

3 ft 3 ft 1. 1 yd2  1  yd  yd       3  3 ft  ft  9 ft2 1 yd

1 yd

2. Length  36 in.  12 in.  48 in.; Width  24 in.  12 in.  36 in.; Area  48 in.  36 in.  1,728 in2

3.

1 ft2 1,728 Area in square feet  1,728  in2  2   ft2  12 ft2 144 i n 144 43,560 ft2 A  1.5  45 4. 55 acres  55 acres     1a cre  67.5 yd2 2 9 ft 67.5 yd2  67.5  yd2  2  55  43,560 ft2 1 yd 2  607.5 ft  2,395,800 ft2 100 dm 2 1m 

100 cm2 1 dm

6. 1 m2  1  m2     2 2

 1g  al

2 pt 1 qt

4 qt 7. 5 gal  5  gal    

 10,000 cm2

1 mi 5. 960 acres  960 acres    2

640 ac  res

960   mi2 640  1.5 mi2 1 gal 4q t

8. 2,000 qt  2,000  qt   2,000   gal 4  500 gal

 5  4  2 qt  40 pt

The number of 10-gal containers in

9.

500 500 gal is   50 containers. 10

1,000 mL 3.5 liters  3.5 liters   1 liter  3.5  1,000 mL  3,500 mL

Section 6.3

16 oz 1. 15 lb  15  lb   1 l b

2,000 lb 1T

2. 5 T  5 T  

 15  16 oz  240 oz

 10,000 lb 10,000 lb is the equivalent of 5 tons

1,000 g  1,000 mg 3. 5 kg  5 kg      4. Total number of milligrams in bottle  75  200  15,000 mg. 1 kg

1 g

 5  1,000  1,000 mg  5,000,000 mg

1g 15,000 mg  15,000  mg   1,000  mg 15,000   g 1,000  15 g

100 cm 

S-13

S-14

Solutions to Selected Practice Problems

Section 6.4

2.54 cm 1. 10 in.  10  in.   1 in .

16.4   m 3.28

10   gal 3.79

 25.4 cm

5m 1,000  mL 1 in3 2.2 liters  2.2 liters     1 liter 16.39  mL

5.

 2.64 gal (rounded to the nearest hundredth) 9 1 kg 165 lb  165  lb   6. F  (40)  32 5 2.20 lb 

2.2  1,000   in3 16.39

165   kg 2.20

 72  32

 134 in (rounded to the nearest cubic inch)

 75 kg

 104°F

3

7.

1 gal 3.79 li E ters

3. 10 liters  10 E liters  

 10  2.54 cm

4.

1m 3.28  ft

2. 16.4 ft  16.4  ft  

5(101.6  32) C   9  38.7°C (rounded to the nearest tenth)

Section 6.5

60 min 1 hr

1. a. 2 hr 45 min  2 hr    45 min

2.

4 min

1 hr 60 min

b. 2 hr 45 min  2 hr  45 min  

 120 min  45 min

 2 hr  0.75 hr

 165 min

 2.75 hr

27 sec

 8 min

45 sec

12 min

73 sec

Since there are 60 seconds in every minute, we write 73 seconds as 1 minute 13 seconds. We have 12 min 73 sec  12 min  1 min 13 sec  13 min 13 sec

3. 6 hr 25 min 

5 hr

42 min 

4. First, we multiply each unit by 4:

85 min

 42 min 5 hr

3 lb

8 oz



43 min

4

12 lb 32 oz To convert the 32 ounces to pounds, we multiply the ounces by the conversion factor 1 lb 12 lb 32 oz  12 lb  32 oz   16 oz  12 lb  2 lbs  14 lb Finally, we multiply the 14 lb and $5.00 for a total price of $70.00.

Chapter 7 Section 7.1 160

140

140

120

120

60

Month

Nov

Sept

July

May

0

Mar

20

0

Month

Nov

40

20

Sept

40

80

July

60

100

May

80

Mar

100

Jan

Precipitation (mm)

160

Jan

Precipitation (mm)

9.

Solutions to Selected Practice Problems

S-15

Section 7.2 1. 2  (5)  3

3. 2  (5)  7

2. 2  5  3

7.  2  (6)  8

15 

8.

12  27

4. 2  6  8

15  (12)  3 15 

5. 2  (6)  4

6. 2  6  4

9. 12  (3)  (7)  5  9  (7)  5 25

12  3

7

15  (12)  27

10. [2  (12)]  [7  (5)]  [14]  [2]

11. 5.76  (3.24)  9.00

12. 6.88  (8.55)  1.67

 12

 6

5 6

2

3 6

1 2

 4  8

1 2

13.       

3

5

14 24



32 42

  8 4 6 5       8  8  8 2 5     8 8 5

14.           

7   8

Section 7.3 1. 7  3  7  (3)

2. 7  3  7  (3)

4

3. 8  6  8  (6)

 10

6. a. 8  5  8  (5)

b. 8  5  8  (5)

3  22

5

d. 8  (5)  8  5

 13

g. 12  (10)  12  10

5. 10  (15)  10  15

 16

c. 8  (5)  8  5

 13

f. 12  10  12  (10)

4. 10  (6)  10  6

 14

e. 12  10  12  (10)

 3

h. 12  (10)  12  10

 22

2

7. 4  6  7  4  6  (7)

 2

 2  (7)  5

8. 15  (5)  8  15  5  (8)

9. 8  2  8  (2)

 20  (8)

10. 7  (5)  7  5

 10

 12

 12

11. 8  (6)  8  6

12. 57.8  70.4  57.8  (70.4)

 2

5 8

3 8

 8

5 8

3

13.       

 128.2

14. 42  (42)  42  42  84°F

8   8  1

Section 7.4 1. 2(6)  (6)  (6)

2. 2(6)  6(2)  (2)  (2)  (2)  (2)  (2)  (2)

 12

3. 2(6)  12

 12

10. 5(2)(4)  10(4)  40

11. a. (8)  (8)(8)  64 2

d. 3  3  3  3  27 3

b. 82  8  8  64

c. (3)3  (3)(3)(3)  27

12. 2[5  (8)]  2[3]

13. 3  4(7  3)  3  4(4)

6

14. 3(5)  4(4)  15  (16)

 3  (16)

 31

 19

15. 2(3  5)  7(2  4)  2(2)  7(6)

16. (6  1)(4  9)  (7)(5)

 4  (42)

3 4

 7 4

3 4 4 7

3 7

17.      

 35

 4  42  46

 6  5

9 20



59 6  20

 33 5 5 2 34

3 8

18.        

19. (3)(6.7)  20.1

20. (0.6)(0.5)  0.30

Section 7.5 8(5) 4

40 4

6.     10

20  6(2) 7  11

20  (12) 4 32   4 8

7.   

8. 3(42)  10  (5)  3(16)  10  (5)  48  (2)  50

9. 80  2  10  40  10  4

S-16

Solutions to Selected Practice Problems

Section 7.6 1. 5(7a)  (5  7)a

2. 3(9x)  (3  9)x

 35a

3. 5(8y)  [5(8)]y

 27x

5. (3x  7)  4  3x  (7  4)

4. 6  (9  x)  (6  9)  x

 40y

6. 6(x  4)  6(x)  6(4)

 3x  11

 15  x

7. 7(a  5)  7(a)  7(5)

 6x  24

8. 6(4x  5)  6(4x)  6(5)

 7a  35

 (6  4)x  6(5)  24x  30

9. 3(8a  4)  3(8a)  3(4)

10. 8(3x  4y)  8(3x)  8(4y)

 24a  12

11. A  s 2  122  144 ft2

 24x  32y

P  4s  4(12)  48 ft

12. A  lw  100(53)  5,300 yd2 P  2l  2w  2(100)  2(53)  200  106  306 yd

Chapter 8 Section 8.1 1. 6(x  4)  6(x)  6(4)

1 2

2. 3(2x  4)  3(2x)  (3)(4)

 6x  24

1 2 x2

 6x  (12)  6x  12

5. 2(4x  3)  7  2(4x)  2(3)  7

1 2

3. (2x  4)  (2x)  (4)

 9x  6

6. 3(2x  1)  5(4x  3)  3(2x)  3(1)  5(4x)  5(3)

 8x  6  7  8x  13

4. 6x  2  3x  8  6x  3x  (2)  8

10. A  lw

 6x  3  20x  15

 25(8  2x)

 26x  12

 25(8)  25(2x)  200  50x

11. a. x  90°  45°  45° b. x  180°  60°  120°

Section 8.2 1.

x3

When

2.

the equation

becomes 5(3)  4  11

becomes

or

a  3

When

5x  4  11

the equation

15  4  11

x  5  2

3.

6a  3  2a  4

x  5  (5)  2  (5)

6(3)  3  2(3)  4

x  0  7

18  3  6  4

11  11

x  7

21  2 This is a false statement, so a  3 is not a solution.

4.

a27

5.

y6289

x  3  3

12  x  2

a09

y  4  (4)  1  (4)

x  3  3  3  3

12  (2)  x  2  (2)

2 5 a     3 6 2 2 5 2 a         3 3 6 3 9 3 a     6 2

Section 8.3 1.

1 x  5 3 1 3  x  3  5 3 x  15

6.

5  7  x  2

7.

y  4  1

a9

8.

6. 5x  3  4x  4  7

a2272

y  0  5

x00

y  5

x0

15a  20  14a  25 a  20  25 a  20  20  25  20 a  45

3.

1 a  3  (3)  7  (3) 5 1 a  4 5 1 5  a  5  4 5 a  20

5x  6  14 5x  6  (6)  14  (6) 5x  20

14  x

9. 5(3a  4)  14a  25

1 a  3  7 5

2.

14  x  0

7.

3 y  6 5 5 3 5   y    6 3 5 3 y  10

3x  7x  5  3  18

4.

3 6 x   4 5 4 3 4 6 (x)     3 4 3 5 8 x   5

8.

5. 6x  42

5  4  2x  11  3x

4x  5  15

1  5x  11

4x  5  (5)  15  (5)

1  11  5x  11  11

5x 20    5 5

4x  20

10  5x

x4

4x 20    4 4

10 5x    5 5

x5

2x

6x 42    6 6 x  7

Solutions to Selected Practice Problems

Section 8.4 1.

4(x  3)  8

6a  7  4a  3

2.

4x  12  8

3. 5(x  2)  3  12

6a  (4a)  7  4a  (4a)  3

4x  12  (12)  8  (12) 4x  20

5x  10  3  12

2a  7  3

5x  7  12

2a  7  (7)  3  (7)

5x  7  7  12  7

4x 20    4 4 x  5

2a  10

5x  5

2a 10    2 2

5x 5    5 5

a  5

4.

3(4x  5)  6  3x  9

x x     9 3 6

5.



x  1

6.



1 5 8 3x    8  4 8

   

1 5 8(3x)  8   8  4 8

x x 6     6(9) 3 6

12x  15  6  3x  9 12x  9  3x  9

x x 6   6   6(9) 3 6

12x  (3x)  9  3x  (3x)  9 9x  9  9

1 5 3x     4 8



  

4 11 5x   3  5x  x 5

   

4 11 5x   5x(3)  5x  x 5

2x  x  54

24x  2  5

3x  54

24x  3 1 x   8

9x  9  9  9  9 9x  18

x  18

9x 18    9 9 x2

8.

1 x  2.4  8.3 5

7a  0.18  2a  0.77

9.

1 x  2.4  2.4  8.3  2.4 5 1 x  10.7 5 1 5(x)  5(10.7) 5

7a  (2a)  0.18  2a  (2a)  0.77 5a  0.18  0.77 5a  0.18  0.18  0.77  0.18

x  53.5

5a  0.95 5a 0.95    5 5 a  0.19

Section 8.5 1. Step 1 Read and list. Known items:

The numbers 3 and 10

Unknown item:

The number in question

Step 2 Assign a variable and translate the information. Let x  the number asked for in the problem. Then “The sum of a number and 3” translates to x  3.

Step 3 Reread and write an equation.

m m

The sum of x and 3 is 10. x3

4 11   3   x 5

7.

 10

Step 4 Solve the equation. x  3  10 x7

Step 5 Write your answer. The number is 7.

Step 6 Reread and check. The sum of 7 and 3 is 10.

2. Step 1 Read and list. Known items:

The numbers 4 and 34, twice a number, and three times a number

Unknown item:

The number in question

Step 2 Assign a variable and translate the information. Let x  the number asked for in the problem. Then “The sum of twice a number and three times the number” translates to 2x  3x.





 

   

20  15x  11x 20  4x 5  x

S-17

S-18

Solutions to Selected Practice Problems

Step 3 Reread and write an equation. 34

m8 m8

is

the sum of twice a number and three times the number

m

m8

4 added to

4

2x  3x

 34

Step 4 Solve the equation. 4  2x  3x  34 5x  4  34 5x  30 x6

Step 5 Write your answer. The number is 6.

Step 6 Reread and check. Twice 6 is 12 and three times 6 is 18. Their sum is 12  18  30. Four added to this is 34. Therefore, 4 added to the sum of twice 6 and three times 6 is 34.

3. Step 1 Read and list. Known items:

Length is twice width; perimeter 42 cm

Unknown items:

The length and the width

Step 2 Assign a variable and translate the information. Let x  the width. Since the length is twice the width, the length must be 2x. Here is a picture.

x (width)

2x (length) Step 3 Reread and write an equation. The perimeter is the sum of the sides, and is given as 42; therefore, x  x  2x  2x  42

Step 4 Solve the equation. x  x  2x  2x  42 6x  42 x7

Step 5 Write your answer. The width is 7 centimeters and the length is 2(7)  14 centimeters

Step 6 Reread and check. The length, 14, is twice the width, 7. The perimeter is 7  7  14  14  42 centimeters.

4. Step 1 Read and list. Known items:

Three angles are in a triangle. One is 3 times the smallest. The largest is 5 times the smallest.

Unknown item:

The three angles

Step 2 Assign a variable and translate the information. Let x  the smallest angle. The other two angles are 3x and 5x.

Step 3 Reread and write an equation. The three angles must add up to 180°, so x  3x  5x  180°

Step 4 Solve the equation. x  3x  5x  180° 9x  180° Add similar terms on left side x  20°

Divide each side by 9

Solutions to Selected Practice Problems

S-19

Step 5 Write the answer. The three angles are, 20°, 3(20°)  60°, and 5(20°)  100°.

Step 6 Reread and check. The sum of the three angles is 20°  60°  100°  180°. One angle is 3 times the smallest, while the largest is 5 times the smallest.

5. Step 1 Read and list. Known items:

Joyce is 21 years older than Travis. Six years from now their ages will add to 49.

Unknown items:

Their ages now

Step 2 Assign a variable and translate the information. Let x  Travis’s age now; since Joyce is 21 years older than that, she is presently x  21 years old.

Step 3 Reread and write an equation.

Joyce Travis

Now

in 6 years

x  21 x

x  27 x6

x  27  x  6  49

Step 4 Solve the equation. x  27  x  6  49 2x  33  49 2x  16 x8

Step 5 Write your answer. Travis is now 8 years old, and Joyce is 8  21  29 years old.

Step 6 Reread and check. Joyce is 21 years older than Travis. In six years, Joyce will be 35 years old and Travis will be 14 years old. At that time, the sum of their ages will be 35  14  49.

6. Step 1 Read and list. Known items:

Charges are $11 per day and 16 cents per mile. Car is rented for 2 days. Total charge is $41.

Unknown items:

How many miles the car was driven

Step 2 Assign a variable and translate the information. Let x  the number of miles the car was driven. Two days rental is 2(11). The cost for driving x miles is 0.16x. Step 3 Reread and write an equation. The total cost is the two days’ rental plus the mileage cost. It must add up to 41. The equation is 2(11)  0.16x  41 Step 4 Solve the equation. 2(11)  0.16x  41 22  0.16x  41 22  (22)  0.16x  41  (22) 0.16x  19 0.16x 19    0.16 0.16 x  118.75 Step 5 Write your answer. The car was driven 118.75 miles. Step 6 Reread and check. The charge for two days is 2(11)  $22. The 118.75 miles adds 118.75(0.16)  $19. The total is $22  $19  $41, which checks with the total charge given in the problem.

7. Step 1 Read and list. Known items:

We have dimes and quarters. There are 7 more dimes than quarters, and the total value of the coins is $1.75.

Unknown items:

How many of each type of coin Amy has

S-20

Solutions to Selected Practice Problems

Step 2 Assign a variable and translate the information. Let x  the number of quarters. Here is a table that summarizes the information in the problem.

Quarters

Dimes

x 0.25x

x7 0.10(x  7)

Number of Value of

Step 3 Reread and write an equation. The value of the quarters plus the value of the dimes must add to 1.75. Therefore, our equation is 0.25x  0.10(x  7)  1.75 Step 4 Solve the equation. 0.25x  0.10(x  7)  1.75 0.25x  0.10x  0.70  1.75 0.35x  0.70  1.75 0.35x  1.05 x3 Step 5 Write your answer. She has 3 quarters. The number of dimes is 7 more than that, which is 10. Step 6 Reread and check. 3 quarters are worth $0.75. 10 dimes are worth $1.00. The total of the two is $1.75, which checks with the information in the problem.

Section 8.6 1.

When the formula becomes

P  80 and w  6 P  2l  2w 80  2l  2(6) 80  2l  12 68  2l

2.

When the formula becomes

F  77

3.

becomes

x0 y  2x  6 y206 06

5 C  (77  32) 9

34  l

When the formula

5 C  (F  32) 9

6

5  (45) 9

The length is 34 feet.

5 45     9 1 225   9  25 degrees Celsius

4.

When

x  3

the formula

2x  3y  4

becomes

2(3)  3y  4 6  3y  4 3y  10 10 y   3

5. a. 11  9  2 hr b. d  60 mi/hr  2 hr

6. With x  35° we use the formulas for finding the complement and the supplement of an angle:

d  60  2

The complement of 35° is 90°  35°  55°

d  120 miles

The supplement is 35° is 180°  35°  145°

Answers to Odd-Numbered Problems Chapter 1 Problem Set 1.1 1. 8 ones, 7 tens 3. 5 ones, 4 tens 5. 8 ones, 4 tens, 3 hundreds 7. 8 ones, 0 tens, 6 hundreds 9. 8 ones, 7 tens, 3 hundreds, 2 thousands 11. 9 ones, 6 tens, 5 hundreds, 3 thousands, 7 ten thousands, 2 hundred thousands 13. Ten thousands 15. Hundred millions 17. Ones 19. Hundred thousands 21. 600  50  8 23. 60  8 25. 4,000  500  80  7 27. 30,000  2,000  600  70  4 29. 3,000,000  400,000  60,000  2,000  500  70  7 31. 400  7 33. 30,000  60  8 35. 3,000,000  4,000  8 37. Twenty-nine 39. Forty 41. Five hundred seventy-three 43. Seven hundred seven 45. Seven hundred seventy 47. Twenty-three thousand, five hundred forty 49. Three thousand, four 51. Three thousand, forty 53. One hundred four million, sixty-five thousand, seven hundred eighty 55. Five billion, three million, forty thousand, eight 57. Two million, five hundred forty-six thousand, seven hundred thirty-one 59. 325 61. 5,432 63. 86,762 65. 2,000,200 67. 2,002,200 69. a. Twenty-eight thousand, six hundred thirty-one b. Ninety-three thousand, three hundred thirty-three 71. Hundred thousands 73. Three million, one hundred seventy-three thousand, four hundred three 75. Twenty-one thousand, four hundred eighty 77. Seven hundred fifty dollars and no cents 79. 304,000,000 81. One hundred twenty-seven million 83. 36,000,000 85. Ten million, nine hundred thousand

Problem Set 1.2 1. 15 3. 14 5. 24 7. 15 9. 20 11. 68 13. 98 15. 7,297 25. 102 27. 875 29. 829 31. 10,391 33. 16,204 35. 155,554 45. 2,220 47. 18,285 49. 51.

53. 69. 81. 95.

17. 6,487 19. 96 21. 7,449 23. 65 37. 111,110 39. 17,391 41. 14,892 43. 180

First Number a

Second Number b

Their Sum a+b

First Number a

Second Number b

Their Sum a+b

61 63 65 67

38 36 34 32

99 99 99 99

9 36 81 144

16 64 144 256

25 100 225 400

95 55. 8  3 57. 4  6 59. 1  (2  3) 61. 2  (1  6) 63. (1  9)  1 65. 4  (n  1) 67. n  4 n5 71. n  8 73. n  8 75. The sum of 4 and 9 77. The sum of 8 and 1 79. The sum of 2 and 3 is 5. a. 5  2 b. 8  3 83. a. m  1 b. m  n 85. 12 in. 87. 16 ft 89. 26 yd 91. 18 in. 93. a. 150 b. 1,125 $349 97. a. $62,377.00 b. $55,177.00 c. $7,200.00

Problem Set 1.3 1. 40 3. 50 5. 50 25. 5,000 27. 39,600

7. 80 9. 460 11. 470 13. 56,780 15. 4,500 17. 500 19. 800 21. 900 29. 5,000 31. 10,000 33. 1,000 35. 658,000 37. 510,000 39. 3,789,000

23. 1,100

Rounded to the Nearest Original Number

41. 43. 45. 47.

7,821 5,999 10,985 99,999

Ten

Hundred

Thousand

7,820 6,000 10,990 100,000

7,800 6,000 11,000 100,000

8,000 6,000 11,000 100,000

Jack in the Box Colossus Burger

Burger King Whopper

McDonald’s Big Mac

Jack in the Box Hamburger

Burger King Hamburger

1000 900 800 700 600 500 400 300 200 100 0 McDonald’s Hamburger

Number of calories

49. 1,200 51. 1,900 53. 58,000 55. 33,400 57. 190,000 59. 81,400 61. a. 4,265,997 babies b. Yes c. 2,300,000 babies d. 112,000 babies 63. 160 miles per hour 65. Answers will vary, but 70 miles per hour is a good estimate. 67.

Answers to Odd-Numbered Problems

A-1

A-2

Answers to Odd-Numbered Problems

Problem Set 1.4 1. 32 3. 22 5. 10 7. 111 9. 312 11. 403 13. 1,111 15. 4,544 27. 152 29. 274 31. 488 33. 538 35. 163 37. 1,610 39. 46,083 41. 43.

45. 57. 71. 77.

17. 15

19. 33

21. 5

23. 33

25. 95

First Number a

Second Number b

The Difference of a and b a–b

First Number a

Second Number b

The Difference of a and b a–b

25 24 23 22

15 16 17 18

10 8 6 4

400 400 225 225

256 144 144 81

144 256 81 144

The difference of 10 and 2 47. The difference of a and 6 83 59. y  9 61. 3  2  1 63. 37  9x  10 $172,500 73. 91 mph 75. 173 GB a. b. 407 MW

State

49. The difference of 8 and 2 is 6. 51. 3 65. 2y  15x  24 67. (x  2)  (x  1)  1

53. 8 55. 23 69. $255

Energy (MegaWatts)

Texas California Iowa Washington

2,768 2,361 936 818

Problem Set 1.5 1. 300 3. 600 5. 3,000 7. 5,000 9. 21,000 11. 81,000 13. 100 15. 228 23. 1,725 25. 121 27. 1,552 29. 4,200 31. 66,248 33. 279,200 35. 12,321 41. 612,928 43. 333,180 45. 18,053,805 47. 263,646,976 49. 51.

17. 36 19. 1,440 21. 950 37. 106,400 39. 198,592

First Number a

Second Number b

Their Product ab

First Number a

Second Number b

Their Product ab

11 11 22 22

11 22 22 44

121 242 484 968

25 25 25 25

10 100 1,000 10,000

250 2,500 25,000 250,000

First Number a

Second Number b

Their Product ab

12 36 12 36

20 20 40 40

240 720 480 1,440

53.

55. The product of 6 and 7

59. The product of 9 and 7 is 63. 61. 7  n 63. 6  7  42 71. Factors: 2, 3, and 4 73. Factors: 2, 2, and 3 75. 9(5) 85. 9(4)  9(7)  99 87. 3x  3 89. 2x  10 91. n  3 101. 148,800 jets 103. 2,081 calories 105. 280 calories 115. 40 117. 54

57. The product of 2 and n

65. 0  6  0 67. Products: 9  7 and 63 69. Products: 4(4) and 16 77. 7  6 79. (2  7)  6 81. (3  9)  1 83. 7(2)  7(3)  35 93. n  9 95. n  0 97. 2,860 mi 99. $7.18 107. Yes 109. 8,000 111. 1,500,000 113. 1,400,000

Problem Set 1.6 1. 6  3 3. 45  9 5. r  s 7. 20  4  5 9. 2  3  6 11. 9  4  36 13. 6  8  48 15. 7  4  28 17. 5 19. 8 21. Undefined 23. 45 25. 23 27. 1,530 29. 1,350 31. 18,000 33. 16,680 35. a 37. b 39. 1 41. 2 43. 4 45. 6 47. 45 49. 49 51. 432 53. 1,438 55. 705 57. 3,020 59. 61. 61 R 4 63. 90 R 1 65. 13 R 7 67. 234 R 6 First Number

Second Number

a

b

100 100 100 100

25 26 27 28

69. 402 R 4 83. 665 mg

71. 35 R 35 85. 5 mi

73. $3,525

The Quotient of a and b a ––– b 4 3 R 22 3 R 19 3 R 16

75. 79¢

77. 3 bottles

79. 6 glasses, with 2 ounces left over

81. $3,900,000

Answers to Odd-Numbered Problems

A-3

Problem Set 1.7 1. Base 4; exponent 5 3. Base 3; exponent 6 5. Base 8; exponent 2 7. Base 9; exponent 1 9. Base 4; exponent 0 11. 36 13. 8 15. 1 17. 1 19. 81 21. 10 23. 12 25. 1 27. 12 29. 100 31. 4 33. 43 35. 16 37. 84 39. 14 41. 74 43. 12,768 45. 104 47. 416 49. 66 51. 21 53. 7 55. 16 57. 84 59. 40 61. 41 63. 18 65. 405 67. 124 69. 11 71. 91 73. 7 75. 8(4  2)  48 77. 2(10  3)  26 79. 3(3  4)  4  25 81. (20  2)  9  1 83. (8  5)  (5  4)  60 85. Mean  3; range  4 87. Mean  6; range  10 89. Median  11; range  10 91. Median  50; range  90 93. Mode  18; range  59 95. 255 calories 97. 465 calories 99. 30 calories 101. Big Mac has twice the calories. 103. a. 78 b. 76 c. 76 d. 47 105. Mean  6,881 students; range  819 students 107. a. 126 b. 126.5 c. 130 d. 28 109. a. $3.73 b. $3.60 c. $0.30 111. 4 113. 16

Problem Set 1.8 1. 25 cm2 3. 336 m2 5. 60 ft2 7. 45m2 9. 16 cm2 11. 2,200 ft2 13. 945 cm2 15. 100 in2 17. Volume  64 cm3; surface area  96 cm2 19. Volume  84 ft3; surface area  108 ft2 21. 420 ft3 23. 124 tiles 25. The area increases from 25 ft2 to 49 ft2, which is an increase of 24 ft2. 27. 8,509 mm2 29. 720 mm2 31. 1,352 ft3 33. a.

b.

PERIMETERS OF SQUARES

AREAS OF SQUARES

Length of each Side (in Centimeters)

Perimeter (in Centimeters)

Length of each Side (in Centimeters)

Area (in Square Centimeters)

1 2 3 4

4 8 12 16

1 2 3 4

1 4 9 16

35. 7 ft

37. 9 ft

Chapter 1 Review 1. One thousand, three hundred seventy-six 3. 5,245,652 5. 1,000,000  20,000  5,000  600  30  9 7. d 9. c 11. b 13. g 15. 749 17. 8,272 19. 314 21. 3,149 23. 584 25. 3,717 27. 173 29. 428 31. 3,781,090 33. 3,800,000 35. 79 37. 222 39. 8 41. 32 43. Mean  79; median  79 45. 3(4  6)  30 47. 2(17  5)  24 49. $488 51. Smallest: 310 yd; Rose Bowl: 376 yd; largest: 390 yd 53. $2,032 55. $1,938 57. $532 59. 1,470 calories 61. 250 more calories 63. No 65. Answers will vary. 67. Volume  160 cm3; surface area  184 cm2

Chapter 1 Test 1. Twenty thousand, three hundred forty-seven [1.1C] 2. 2,045,006 [1.1D] 3. 100,000  20,000  3,000  400  7 [1.1B] 4. f [1.2B] 5. c [1.5B] 6. a [1.2B] 7. e [1.5B] 8. 876 [1.2A] 9. 16,383 [1.1A] 10. 524 [1.4A] 11. 3,085 [1.4B] 12. 1,674 [1.5A] 13. 22,258 [1.5A] 14. 85 [1.6B] 15. 21 [1.6B] 16. 520,000 [1.3A] 17. 11 [1.7B] 18. 4 [1.7C] 19. 107 [1.5B] 20. 3x  6 [1.5B] 21. $264,300; $142,000; $125,000 [1.7D] 22. 2(11  7)  36 [1.6A] 23. (20  5)  9  13 [1.6A] 24. [1.3B] Urban Area Los Angeles Washington Seattle-Everett Atlanta Boston

25. Perimeter  14 ft; area  12 ft2 [1.8A]

Average Hours in Gridlock Per Year 52 35 32 34 29

26. 70 cm3; 118 cm2 [1.8A]

A Glimpse of Algebra 1. 36x 2 3. 16x 2 5. 27a3 5 5 21. 432x y 23. 400x 6y 6z 6

7. 8a3b3 9. 81x 2 y 2 11. 25x 2 y 2z 2 13. 1,296x 4y 2 5 7 6 14 16 11 12 25. x y z 27. 324a b 29. 40x y

15. 576x 6

17. 200x 5

19. 7,200a7

A-4

Answers to Odd-Numbered Problems

Chapter 2 Getting Ready for Chapter 2 1. a. b. c.  d. 2. 10 3. 2 4. 16 5. 23 13. 201 R 5 14. 507 R 10 15. (2  3)  7 16. 22  33

6. 16

7. 0

8. 24

9. 101

10. 5

11. 2 R 3

12. 8 R 16

Problem Set 2.1 1. 1

3. 2

5. x

19. True 120a 24a

11. 1

3 4

13. 12

43 47

4 3

25. 

1 16 1 1 8 4

5 3 8 4

15 16

5 4

1

Denominator

a

b

3

5

3  5

1

7

1  7

x

y

x  y

x1

x

x1  x

4 6

29.  47. 3

1 20

5 6

31.  49. 2

4 25

33.  51. 37

3 10

8 12 1  2

35.  53. a.

3 1 9 4 2 10

17. , , 

Fraction a  b

8 12 1 c.  4

1 2

b. 

48a 24a

2x 12x

37. 

41. 

39.  1 4

d. 

3 12

2 5

67.  inch

65.          

2

4  25

1 to 5 times a day

47  100

5 to 10 times a day

8  25

more than 10 times a day

1  20

83. 108

85. 60

87. 4

311 500

4 5

89. 5

19 33

73. 

71. 

Fraction of Respondents Saying Yes

never

81. a

Numerator

13 17

27. 

31 16

15 8

3 2

How Often Workers Send Non-Work-Related E-Mail From the Office

79. d

15.

Answers will vary

45.

0 69.

9. 5

23. 

21. False

43. 

55.–63.

7. a

91. 7

90 360

75. 

93. 51

45 360

180 360

270 360

77. a.  b.  c.  d. 

95. 23

97. 32

99. 16

101. 18

Problem Set 2.2 1. Prime 17. 45. 55.

1  2 17  19 9  16

3. Composite; 3, 5, and 7 are factors 19.

2  3

21. 14 33

4  5

9 23.  5 2 a.  17

47. 

49.

57.–59.

1 2

=

2 4

=

4 8

1 4

=

2 8

=

4 16

=

25. 3 26

b.  c.

1 3 53

95.

1 8

73. 

3 2

8 16

0 71. 

7  11

=

6 4

=

10 8

=

20 16

12 8

1

75. 3

77. 45

5. Composite; 3 is a factor

3 27.  5 3 1  d.  28 9 =

24 16

1 29.  7 2 e.  19

31.

7  9

33. 1 45

51. a.  b. 106 115

61. 

1 3

63. 

8 15

7 8

3. 

5. 1

27 4

7. 

35.

1  5

1 18

9. 22  3 37. 1 15 1 67.  3

39. 1 10

8 25

5  3

41. 1 3

c.  d.  e. 

65. 

13. 5  43

11. 34

11  7

15. 3  5

8  9

=

79. 25

81. 22  5  3

83. 22  5  3

9. 1

1 24

11. 

24 125

13. 

105 8

15. 

85. 9

87. 25

5 6

53. a.  b.  c. 37 70

69. 

89. 12

91. 18

42 55 1  5

43. 

2 5 4

Problem Set 2.3 1. 

7. Prime 7  5 1  30

93. 42

A-5

Answers to Odd-Numbered Problems 17.

19.

First Number x

Second Number y

Their Product xy

1  3

1  2

30

15

3  4

1  2

1  5

30

6

3  4

4  5

3  5

1  6

30

5

5  a

a  6

5  6

1  15

30

2

First Number x

Second Number y

Their Product xy

1  2

2  3

2  3

1 15

9 16

21. 

3 5

23. 9

25. 1

47. 4

49. 9

51. ; numerator should be 3, not 4.

53. a.

4 9

29. 

27. 8

31. 

8 27

1 4

33. 

35. 

1 2

37. 

39. 

9 100

41. 

43. 3

3 10

Number x

Square x2

1 2 3 4 5 6 7 8

1 4 9 16 25 36 49 64

b. Either larger or greater will work.

55. 133 in2

4 5 7 59. 3 yd2 61. 138 in2 63. a.  in. b.  in. c. 3 in. 65. 126,500 ft3 10 9 4 1 8 Canada: 1,668,000 Venezuela: 1,251,000 Iraq:  834,000 73.  75.  27 27 4 1  89. 3 91.  93. 100 95. 9 97. 18 99. 8 3 7

57.  ft2

67. About 8 million

71.

77. 2

87.

45. 24

79. 3

81. 2

69. 846 83. 5

Problem Set 2.4 15 4 2  9

4 3

1.  27.

3. 

5. 9 4 5

1 5

15 22

31. 

29. 9

33. 

5 1

51. 3    3    3  5 63.

3  6

83.

65.

9  6

67.

3 8

9. 

7. 200

69.

Number

8  12

49 64

13.  7 10

37. 

35. 40

53. 490 feet 4  12

11. 1

39. 13

55. 14 blankets 71.

14  30

73.

3 4

15. 

41. 12

57. 6

18  30

43. 186

77.

4  24

5 18 3  5

23. 

21. 6 45. 646

47.

61. 20 lots 15 36

79. 

9 36

81. 

85. b

Rounded to the Nearest Ten

1 6

19. 

59. 28 cartons 12  24

75.

15 16

17. 

Hundred

Thousand

74

70

100

0

747

750

700

1,000

474

470

500

0

Problem Set 2.5 2 3

1.  17.

1 4

3. 

1 2

5. 

1 3

7. 

3 2

9. 

x6 2

11. 

First Number a

Second Number b

The Sum of a and b ab

1  2

1  3

1  3

4 5

13.  19.

10 3

15.  First Number a

Second Number b

The Sum of a and b ab

5  6

1  12

1  2

7  12

1  4

7  12

1  12

1  3

5  12

1  4

1  5

9  20

1  12

1  4

1 4     3 12

1  5

1  6

11  30

1  12

1  6

3 1     12 4

9 2

25.  49. 40

85. 3

A-6

Answers to Odd-Numbered Problems

7 9 13  420

21.  45.

7 3

23.  41 24

47. 

5 4

55. 

1 3

75. 

97. 

33.  3 4

53. 

9 8

95. 

19 24

31.  88 9

51. 

73.  hours 17 8

93. 

29. 

5 3

71.  11 4

91. 

53 60

49. 

7 10

9 20

7 6

27. 

61 400

9 2

69.  pints 8 8

7 4

25. 

1 4

57. 

37. 

59. 19

61. 3

3 2

77. 10 lots

99. 2 R 3

31 100

13 60

35. 

67 144 160  63

39.  63.

9 5

7 3

5 8

81.  ft

83. 

85. 3

9 10

105. 8

107. 3

109. 2

103. 

949 1,260

43.  7 20

65. 

79.  in.

101. 8 R 16

29 35

41. 

67.  inch 16 8

89. 

87. 59 2 7

15 22

111. 

113. 

Problem Set 2.6 14 3 11  4

21 4 37 27.  8

1.  25.

13 8

3. 

47 3

5. 

104 21

7. 

9.  9 40

14 5

29. 

427 33 32 35.  35

11.  3 8

31. 

33. 

1 8 4  7

13. 1 37.

3 4 4  5

5 6

15. 4 39.

1 4

17. 4 41. 9

1 27

19. 3

8 15

21. 4

23. 28

43. 98

Problem Set 2.7 1 10 1 3 5

2 3 1 2 8

93 100 1 7 2

1. 5

3. 13

5. 6

27.

29.

31.

2

33.

9

45. $2,516 

3 4

1 5

9. 9

1 2

11. 3 1 2

1 3

35. 5 cups

32 45

9 20

13. 12

15. 9

17. 

1 5

37. 1

2 3

19. 1 3 4

39. 2,687 cents

41. 163 mi

3 10

23. 4

21. 4

1 10

25. 

758

43. 6  shares 1,207

7

47. 182  ft2

3

5 6 11  13

7. 5

49. 3  mi2

16

16

1

1

51. Can 1 contains 157 calories, whereas Can 2 contains 87 calories. Can 1 contains 70 more calories than Can 2. 2 2 53. Can 1 contains 1,960 milligrams of sodium, whereas Can 2 contains 1,050 milligrams of sodium. Can 1 contains 910 more milligrams of sodium than Can 2. 10 3 9 15 15 15

5 15

12 20

5 20

55. a.  b.  c.  d. 

18 20

2 20

57. a.  b.  c.  d. 

13 15

61.  = 1

14 9

1 12

17. 26

59. 

5 9

3 5

1 4

3 14

63. 

65. 

1 16

67. 2

69. 3

Problem Set 2.8 7 19. 12 12 4 1 1 17 6 10 29. 2 31. 21 33. 9 37. 14 39. 17 41. 24 43. 27 15 15 24 20 7 2 11 11 19 13 1 1  53. 1 55. 3 57. 5 61.  63. 3 65. $2 67. $250 3 12 12 20 24 2 2 2 2 a. NFL: P  306 yd; Canadian: P  350 yd; Arena: P  156 yd 3 3 1 2 b. NFL: A  5,333  sq yd; Canadian: A  7,150 sq yd; Arena: A  1,416 sq yd 3 3 1 63 11 3 5 31 in. 75. 4 77. 2 79.   1 81. 3 83. 17 85. 14 87. 104 89. 96 6 64 8 8 8 29 4 5 97. 34 40 5 4 5

2 5

1. 5 27. 51. 71.

73. 95.

4 9

3. 12

5. 3

Problem Set 2.9 1. 7 29. 53.

3. 7 3  5 2 5 5

5. 2

31.

7  11

7 8 17  28

9. 

7. 35 33. 5

55. 8

3 8

9. 1

7. 12

35.

57. 5 miles2

1 6 1 35. 18 10 1 59. 5 2

11. 14

1 3 7 37. 1 16 2 115 yd 3

11. 8

59.

1 12

13. 4

11 36 13 39.  22 2 61.  3

13. 

15. 2

2 3 5  22

15. 3 41. 1 6

3 8 15  16

17. 6 43. 1 7

63. 

5 12 5 1 17

19. 4 45.

47.

6 7 7 9 10

3 8 1 5 2

23. 8

25. 3

45.

47.

49.

69. $300

8 9 3  29

21. 

1 2 1 6 4

21. 2

1 2

93. 3

91. 40

1 2

1 10

23.  49.

25. 1

34 1 67

51.

27. 5

346  441

7 9

65. 

67. 9

Chapter 2 Review 3 4

11 7

1. 

3.  2 3

29. 11

31. 5

2 3

8 21

7. 

5. 1

1 2

33. 

3 8

9. 

1 2

11. 

35. 20 items

7 2

13. 

15.  7 8

39. 1 cups

37. 9

29 1 19.  8 36 1 10 tablespoons 2

17.  41.

3 4

11 8 25. 12 27. 17 12 13 1 Area  25 ft2; perimeter  28 ft 5

21. 3 43.

23. 

Chapter 2 Cumulative Review 1. 17 27.

55  36

3. 1844 29.

19 2 36

5. 1 4

7. 3 4

31. 192 in

2

9. 137,280 33.

16 5 19

11. 354 35.

2  7

37.

13. 2 5

46 1   1 45 45

15. 25

17. 6

39. 70 pictures

19. 1 7

21. 1

1 23. 8 125

25. 147 12

A-7

Answers to Odd-Numbered Problems

Chapter 2 Test 2 3

13 5

2. a.  b.  [2.2C]

1. [2.1C]

1 10

2 5

6.  [2.4A]

3 8

7.  [2.5A] 9 2

9.  [2.5B]

17 24

1 2

47 36

10.  [2.5B]

2 3

16. 9 [2.8A]

13. 8 [2.6B] 1 2

19. 9 [2.9A]

2 15

3 5

12.  [2.6A] 11 12

18. 16 [2.9A]

23. 9 cups [2.7C]

37 7

11.  [2.5B] 3 4

17. 3 [2.8B] 1 3

22. 27 in. [2.8C]

21. 40 grapefruit [2.2D]

7 10

23 5

8.  [2.5A]

15.  [2.7B]

14. 26 [2.6D]

8 27

5.  [2.4A]

7 – 8

5 – 8

3 – 8

1 – 8

8 35

4.  [2.3A]

3. 18 [2.7A]

20.  [2.9B] 1 3

24. 3 ft [2.7C]

1 3

25. Area  23 ft2; perimeter  23 ft

A Glimpse of Algebra x3 4 12  x 21.  4

1. 

x2 7x 2 5.  7.  5 8 x 10  x 28  a 23.  25.  2 7

3x  2 6 5  2a 27.  5

3. 

9. 

2x  1 4 8x  3 29.  x

11. 

12x  3x 4x 2x  5 31.  x

4x  5 5x 4x  3 33.  4

13. 

7x  24 12x 11x 35.  9

15. 

3x  4 4x

17. 

19.  3a 7

37. 

5x 4

39. 

Chapter 3 Getting Ready for Chapter 3 1. 407,927 2. 25,576 3. 436 4. 663 1 3 41 12.  13.  14. 1 15. 9,200 16

10

5. 132,980 6. 728 7. 12,768 19 4 16.  17. 2  3 18. 22  32  5

64

8. 96

9. 1,848

3. Fifteen thousandths

234 305 15.  1,000 100,000 11.11 33. 100.02 1 1 5  45.  47.  4 8 8

13. 1 31. 43.

5. Three and four tenths

17. Tens

19. Tenths

7  8

49.

51. 9.99

7. Fifty-two and seven tenths

21. Hundred thousandths

37. a.  b.

35. 3,000.003

11. 74

50

Problem Set 3.1 1. Three tenths

10. 298 R 14

23. Ones

25.

36 9 11. 9 100 1,000 Hundreds 27. 0.55 29. 6.9

9. 405

39. 0.002 0.005 0.02 0.025 0.05 0.052

53. 10.05

55. 0.05

41. 7.451, 7.54

57. 0.01

Rounded to the Nearest Number

Whole Number

59. 47.5479 61. 0.8175 63. 0.1562 65. 2,789.3241 67. 99.9999 69. Hundredths

71.

Tenth

Thousandth

48

47.5

47.55

47.548

1

0.8

0.82

0.818

0

0.2

0.16

0.156

2,789

2,789.3

2,789.32

2,789.324

100

100.0

100.00

100.000

73. Three and eleven hundredths; two and five tenths

PRICE OF 1 GALLON OF REGULAR GASOLINE Date

Price (Dollars)

5/5/08 5/12/08 5/19/08 5/26/08

3.903 3.919 3.952 4.099

31 100

77. 6

75. Fifteen hundredths

Hundredth

23 50

79. 6

123 1,000

81. 18

3 16

3 10

3 8

3 4

83.       

85. 

87.

Problem Set 3.2 1. 6.19 3. 1.13 5. 6.29 7. 9.042 9. 8.021 11. 11.7843 13. 24.343 15. 24.111 17. 258.5414 19. 666.66 21. 11.11 23. 3.57 25. 4.22 27. 120.41 29. 44.933 31. 7.673 33. 530.865 35. 27.89 37. 35.64 39. 411.438 41. 6 43. 1 45. 3.1 47. 5.9 49. 3.272 51. 4.001 53. 1.47 seconds 55. $1,571.10 57. 4.5 in. 59. $5.43

61. 6.42 sec

75. 1,400

3  20

77.

79.

63. 2 in. 147  1,00 0

65. $3.25; three $1 bills and a quarter 81. 132,980

83. 2,115

85. 12

67. 3.25

87. 16

89. 20

3 100

69.  91. 68

51 10,000

71. 

1 2

73. 1

A-8

Answers to Odd-Numbered Problems

Problem Set 3.3 1. 0.28 3. 0.028 5. 0.0027 7. 0.78 9. 0.792 11. 0.0156 13. 24.29821 15. 0.03 17. 187.85 19. 0.002 21. 27.96 23. 0.43 25. 49,940 27. 9,876,540 29. 1.89 31. 0.0025 33. 5.1106 35. 7.3485 37. 4.4 39. 2.074 41. 3.58 43. 187.4 45. 116.64 47. 20.75 49. 371.34 meters 51. 0.126 53. Moves it two places to the right 55. $1,381.38 57. a. 83.21 mm b. 551.27 mm2 c. 1,102.53 mm3 59. 1.18 in2 61. C  25.12 in.; A  50.24 in2 63. C  24,492 mi 65. 168 in. 67. 100.48 ft3 69. 50.24 ft3 71. 1,879 73. 1,516 R 4 75. 298 77. 34.8 79. 49.896 3 10

2 5

1 2

4 5

3 2

83.       

81. 825

2 3

5 6

25 12

85.   1  1  

87. No

Problem Set 3.4 1. 19.7 3. 6.2 5. 5.2 7. 11.04 9. 4.8 11. 9.7 13. 2.63 15. 4.24 17. 2.55 19. 1.35 21. 6.5 23. 9.9 25. 0.05 27. 89 29. 2.2 31. 1.35 33. 16.97 35. 0.25 37. 2.71 39. 11.69 41. 3.98 43. 5.98 45. 0.77778 47. 307.20607 49. 0.70945 51. 3,472 square miles 53. 7.5 mi 55. $6.65/hr 57. 22.4 mi 59. 5 hr 61. 7 min 63. Rank

Name

Number of Events

Total Earnings

1. 2. 3. 4. 5.

Lorena Ochoa Annika Sorenstam Paula Creamer Seon Hwa Lee Jeong Jang

25 13 24 28 27

$1,838,616 $1,295,585 $891,804 $656,313 $642,320

65. 2.73

67. 0.13

89. 0.875

81. 19

3 4 3

2 3

69.  93.

3 4

71. 

$73,545 $99,660 $37,159 $23,440 $23,790

6 10

19 50

73. 

Average per Event

75. 

60 100

77. 

12 15

79. 

81. 

60 15

83. 

18 15

85. 

87. 0.75

Problem Set 3.5 1. 0.125 5.

3. 0.625

Fraction

1  4

Decimal 0.25

15. 0.27 21.

2  4

3  4

4  4

0.5

0.75

1

17. 0.09

Decimal 0.125 1 Fraction  8

1  6

Fraction

2  6

Decimal 0.16  0.3 

3  6

4  6

0.250 1  4

0.375 3  8

0.500 1  2

41. 0.3

0.750 3  4

43. 0.072

0.875 7  8

45. 0.8

9. 0.48

6  6

3 20

2 25

23. 

Gain ($)

Monday, March 6, 2008 Tuesday, March 7, 2008 Wednesday, March 8, 2008 Thursday, March 9, 2008 Friday, March 10, 2008

69. 226.1 ft3

13. 0.92

47. 1

27. 

4 10

2 5

51. 4   4

49. 0.25

3 50

3 5

29. 5

31. 5

11 50

33. 1

53. $16.22

61. 104.625 calories

63. $10.38

As a Decimal ($) (To the Nearest hundredth)

3  4 9  16 3  32 7  32 1  16

71. 22.28 in2

11. 0.4375

3 8

25. 

CHANGE IN STOCK PRICE

Date

67. 33.49 m3 87. 20,675

0.625 5  8

5  6

0.5 0.6  0.83  1

19. 0.28

35. 2.4 37. 3.98 39. 3.02 55. $52.66 57. 9 in. 59.

65. Yes 85. 852

7.

0.75 0.56 0.09 0.22 0.06

1 81

73. 

25 36

75. 

77. 0.25

79. 1.44

81. 25

Problem Set 3.6 1. 8 3. 9 5. 6 7. 5 9. 15 11. 48 13. 45 15. 48 17. 15 19. 1 21. 78. 23. 9 25. 31. True 33. 10 in. 35. 13 ft 37. 6.40 in. 39. 17.49 m 41. 1.1180 43. 11.1803 45. 3.46 51. 0.58 53. 12.124 55. 9.327 57. 12.124 59. 12.124 61. 6.7 miles 63. 30 ft 65. 25 ft 2 8 5 2 4 71. 25  3 73. 25  2 75. 4  10 77. 2 79. 2  7 81. 2  3 83.  85. 9 87. 8 89. 5

25

4  7

47. 67.

4 2 5

83. 100

3 4 11.18 5 miles 7 91.  16

27. 

29. False 49. 0.58 69. 16  2 93. 19

A-9

Answers to Odd-Numbered Problems

Chapter 3 Review 1. Thousandths 3. 37.0042 21. 2.42 23. 79 25. 15

5. 98.77 27. 47

7. 5.816

9. 36.381

11. 7.65

13. 7.09

141 200

1 8

17. 

15. 0.875

19. 14

Chapter 3 Cumulative Review 1. 4,079

3. 16,072

5. 6.22

23. 0.94

25. 147

27. 10 in.

8

1 2

3 4

9. 

7. 55.728

11. 15

13. 20

17. 3(13  4)  51

15. 9

7 9

21. 

19. False

29. $9.60

Chapter 3 Test 1. Five and fifty-three thousandths [3.1B] 6. 6.056 [3.2A]

7. 35.568 [3.3A]

13. 17.129 [3.6A]

2. Thousandths [3.1A]

8. 8.72 [3.4A]

14. 0.26 [3.6A]

3. 17.0406 [3.1A]

9. 0.92 [3.1C]

15. 36 [3.9A]

16.

10.

5  [3.8A] 9

4. 46.75 [3.1D]

14  [3.1C] 25

5. 8.18 [3.2A]

11. 14.664 [3.6A]

17. $11.53 [3.2B]

12. 4.69 [3.6A]

18. $24.47 [3.3B]

19. $6.55 [3.3B]

20. 5 in.

A Glimpse of Algebra 1. 6x 2  9x  8

3. 5a  8

5. 9x  6

7. 5y3  5y2  9y  7

9. 6x 2  4x  5

11. 3a2  7a  6

13. 5x 3  7x 2  16x  13

Chapter 4 Getting Ready for Chapter 4 1 3 3  2

1.  14.

2. 2

3. 0.25

15. 8.7

4. 0.125

5. 65

6. 1.2

7. 297.5

8. 4

9. 8

10. 12

11. 62.5

12. 0.695

13. 3.98

16. 6.5

Section 4.1 4 3 11  14

1.  27.

39. 18

16 2 5.  3 5 20 mg 29.  1 mL

3. 

41. 62.5

1 3 9.  2 1 75 mg  33. 2 mL

7.  31.

43. 0.615

7 6 13  8

11.  a.

45. 176

7 5

13.  1 4

3 8

b.  c.  d.

47. 184

5 7 13  3

15. 

49. 0.087

8 5

6 1

1 3 5  1

51. 0.048

53.

17. 

19. 

35. a.  b.

1 10

3 25 4 3 4 c.  d.  e.  1 1 1 5 11 1  55.   5 8 2 2

21. 

23. 

1 2 44  39

1 3 1  1

2 3 6  7

25. a.  b.  c.  37. a. 5 14

57. 

b.

c.

59. 96

Section 4.2

1 13. The Midwest 15. 480 mL/hr 3 4.95¢ per oz 19. 34.7¢ per diaper, 31.6¢ per diaper; Happy Baby 21. $1.00  0.646 Euros 23. $1.00  0.509 pounds The 18 oz box is the best buy at $0.277 per ounce. 27. 54.03 mi/hr 29. 9.3 mi/gal 31. $64 33. $16,000 35. n  6 7 11 5 1 1 n4 39. n  4 41. n  65 43.  45.  47.  49.   1 51. The 100 ounce size is the better value. 8 6 6 40 60

1. 55 mi/hr 17. 25. 37.

3. 84 km/hr

5. 0.2 gal/sec

7. 14 L/min

9. 19 mi/gal

11. 4 mi/L

Problem Set 4.3 7. n 9. y 11. n  2 13. x  7 15. y  7 17. n  8 19. a  8 21. x  2 1 1 29. x  3 31. n  7 33. y  1 35. y  9 37. n  3 39. x  3 41. a  22

1. 35 3. 18 5. 14 25. a  6 27. n  5 0 45. y  1 13

67. 22 5

2

47. x  21

49. n  11

2

69. 13 4

2

3 4

51. 

53. 1.2

55. 6.5

57. 0.75

59. 5.5

2

61. 0.03

5

23. y  1 43. y  4

63. 0.375

7

7 65. 1 50

7 8

71. 

Section 4.4

1 2 14

1 3

1. Means: 3, 5; extremes: 1, 15; products: 15 3. Means: 25, 2; extremes: 10, 5; products: 50 5. Means: , 4; extremes: , 6; products: 2 7. Means: 5, 1; extremes: 0.5, 10; products: 5 1 27. 50 29. 108 31. 3 33. 1 35.  4 51. 5 53. Tens 55. 26.516 57. 0.39

12

3

10

9. 10 11.  13.  15.  17. 7 19. 5 2 9 37. 108 39. 65 41. 41 43. 108 45. 20

21. 18 23. 6 47. 297.5 49. 450

25. 40

Section 4.5 1. 329 mi 3. 360 points 5. 15 pt 7. 427.5 mi 9. 900 eggs 11. 35 mg/pill 17. 435 in.  36.25 ft 19. $313.50 21. 265 g 23. 91.3 L 25. 60,113 people 31. 15 mL 33. 900 mg/day 35. 2 37. 147 39. 20 41. 147 43. 1.35

13. 5.5 mL 15. 2.5 tablets 27. 78 teachers 29. 850 meters 45. 3.816 47. 4 49. 160 51. 183.79

A-10

Answers to Odd-Numbered Problems

Section 4.6 1. 9

3. 14

5. 12

7. 25

9. 32

11.

13. E

D

15.

F

F

17.

21. 960 pixels

19. 45 in.

23. 1,440 pixels

25. 57 ft

G H

G F

27. 177 ft 29. 13.99 31. 40.999 33. 0.10545 1 1 41. a.  b. 18 rectangles should be shaded. c.  2

1 6

37. 4

35. 18

39. 4

3

Chapter 4 Review 3 3 7 1 1 9 1 3.  5.  7.  9.  11.  13.  15. 19 mi/gal 10 4 5 2 3 2 4 9.05¢/ounce; 8.41¢/ounce; 32-ounce carton is the better buy. 19. 49 9 31. 160

1.  17. 29.

1 10

21. 

23. 1,500 mL

25. 5 weeks

27. 3 tablets

Chapter 4 Cumulative Review 5 1. 10,522 3. 18 5. 5063 7. 47 9. 74 11. 310 13. 71.48 15. 4.5 17. 80 19. 2 21. 0.94 42 31 2 3 25. P  42 in.; A  72 in [1.2D, 1.8B] 27. a. 18.84 ft b. 565.2 ft [4.5C] 29. 20 women [6.1B] 31. 97 mi [1.7D] 33. 8.5¢/ounce; 13.5¢/ounce; 72-ounce carton is the better buy [6.2C]

23. 25

Chapter 4 Test 4

3

9

3

3

24

6

1.  [4.1A] 2.  [4.1A] 3.  [4.1A] 4.  [4.1A] 5.  [4.1A] 6.  [4.1B] 7.  [4.1B] 8. 23 mi/gal [4.2A] 3 2 5 5 10 10 25 9. 16-ounce can: 16.2¢/ounce; 12-ounce can: 15.8¢/ounce; 12-ounce can is the better buy [4.2C] 10. 36 [4.3B] 11. 8 [4.3B] 12. 24 hits [4.4A] 13. 135 mi [4.4A] 14. a. LGB b. twice as large [4.5B] 15. h  16 [4.5A] 16. h  300 [4.5B] 17. 27 mg 18. 33.15 mg

A Glimpse of Algebra 1. x 2  6x  8 3. 6x 2  13x  6 5. 21x 2  34x  8 7. x 2  7x  10 9. 2x 2  11x  12 13. 9x 2  12x  4 15. 4a2  9a  5 17. 42y 2  111y  72 19. 8  24x  18x 2

11. 14x 2  41x  15

Chapter 5 Getting Ready for Chapter 5 1. 141.44 9 200

13. 

2. 225 65 2

14. 

15. 0.375

13 40 0.416 

4. 

3. 1,477,432 16.

5. 20 17. 2.5

6. 489 18. 62.5

7. 9.45

8. 0.352

19. 15,300

9. 0.0362

10. 117.2

11. 4

9 25

12. 

20. 2,976.74

Section 5.1 20 100 45% 1  16

65 9. 0.23 11. 0.92 13. 0.09 15. 0.034 17. 0.0634 19. 0.009 21. 23% 23. 92% 100 3 3 1 53 7,187 3 29. 31. 80% 33. 27% 35. 123% 37.  39.  41.  43.  45.  47.  5 4 25 200 10,000 400 1 53. 50% 55. 75% 57. 33% 59. 80% 61. 87.5% 63. 14% 65. 325% 67. 150% 69. 48.8% 3 27 7 3 3 a. 0.506 b. 0.527 c. 0.537 73. a.  ,  ,  ,  b. 0.54, 0.28, 0.15, 0.03 c. About two times as likely 75. 78.4% 50 25 20 100 11.8% 79. 72.2% 81. 18.5 83. 10.875 85. 0.5 87. 62.5 89. 0.5 91. 0.125 93. 0.625 95. 0.0625 0.3125 99. 2 101. 2 103. 2 105. 2

1.  25. 49. 71. 77. 97.

60 100 27. 3% 1 51.  3

3. 

24 100 60%

5. 

7. 

Section 5.2 1. 8 3. 24 5. 20.52 7. 7.37 27. 120 29. 13.72 31. 22.5

9. 50% 11. 10% 13. 25% 15. 75% 17. 64 19. 50 21. 925 33. 50% 35. 942.684 37. 97.8 39. What number is 25% of 350?

23. 400

25. 5.568

A-11

Answers to Odd-Numbered Problems 43. 46 is 75% of what number? 45. 4.8% calories from fat; healthy 41. What percent of 24 is 16? 5 3 7 47. 50% calories from fat; not healthy 49. 0.80 51. 0.76 53. 48 55. 0.25 57. 0.5 59.  ,  ,  8 4 8 1 1 3 1 5 3 7 65. 0.75 67. 0.125 69. 0.375 71.  ,  ,  ,  ,  ,  , 

1 4

61. 

63. 0.25

8 4 8 2 8 4 8

Section 5.3 1. 70% 3. 84% 5. 45 mL 7. 18.2 acres for farming; 9.8 acres are not available for farming 9. $11.20 11. Bush 286; Kerry 251 13. 34,266,960 15. 3,000 students 17. 400 students 19. 1,664 female students 23. 50% 2 3

45. 

25. About 19.2 million 47. 39.4%

49. 94 hits

27. 33

29. 8,685

31. 136

33. 0.05

35. 15,300

37. 0.15

39.

21. 31.25% 1  5

5 12

41. 

3 4

43. 

51. At least 16 hits

Section 5.4 1. $52.50 3. $2.70; $47.70 5. $150; $156 7. 5% 9. $420.90 11. $2,820 13. $200 15. 14% 17. 26.9% 19. 62.8 cents or $0.628% 21. $560 23. $11.93 25. 4.5% 27. $3,995 29. 1,100 31. 75 33. 0.16 35. 4 39. 415.8

1 2

2 3

41. 

1 2

43. 2

45. 1

37. 396

1 2

47. 4

Section 5.5 1. $24,610 3. $7,020 21. 21.8 in. to 23.2 in. 37. 10,456.78

5. $13,200 7. 10% 9. 20% 11. 21% 13. $45; $255 23. $46,595.88 25. a. 51.9% b. 7.8% 27. 140 29. 4

39. 2,140

41. 3,210

43. 1

5 12

3 4

45. 

47. 1

15. $381.60 31. 152.25

17. 13.9% 33. 3,434.7

19. 16% 35. 10,150

49. 6

Section 5.6 1. $2,160 3. $665 5. $8,560 7. $2,160 9. $5 11. $813.33 13. $406.34 2 21. a. $13,468.55 b. $13,488.50 c. $12,820.37 d. $12,833.59 23. 30% 25. 16%

15. $5,618 17. $8,407.56 27. 108 29. 162 31. 8

3 1 3 2 3 1 1 16 1 64 37.  39.  41.   1 43.  45. 1 47.  49.  51. $30.78 2 8 3 2 2 4 21 12 525 Percent increase in production cost: Star Wars 1 to 2  63.6%; Star Wars 2 to 3  80.6%; Star Wars 3 to 4  253.8%

19. $974.59 33. 3

35.  53.

Section 5.7

38 41 41 100 240 people

31 31 50 19 960 people

1. a.  b.  c.  d.  5. a.

b.

3. a. 78% b. 10% c. 18% d. 22% c. 750 people d. 1,800 people

7.

9.

A 25%

Bedrooms 37% Living Room 25%

B 40%

Bathrooms 8%

C 35%

Kitchen 17% Dining Room 13%

11.

8 2  or 2 3 3

13.

1  40

15.

73 13  or 3 20 20

Chapter 5 Review

17.

62 12  or 2 25 25 3

19.

9

4 1  or 1 3 3 2

1. 0.35 3. 0.05 5. 95% 7. 49.5% 9.  11. 1 13. 30% 15. 66% 20 4 3 25. $477 27. $4.93 29. 55.4% increase 31. $60; 20% off 33. $42 35. First 4% Business 18%

Coach 78%

17. 16.8

19. 50%

21. 80

23. 75%

A-12

Answers to Odd-Numbered Problems

Chapter 5 Cumulative Review 1. 7,714 25. 67

3. 45,084 27. 20%

125 216 100°C

7. 

5. 33 29. 47¢

31.

1 6

23 24

11. 

9. 1.322 33. 12.5%

13. 

15. 42

17. 6

1 4

19. 

37. P  34 in., A  72.25 in2

35. 34

23 50

23. 

21. 648 in2

39. $7 per hour

Chapter 5 Test 1. 0.18 [5.1B] 7 9.  [5.1A] 200 16. 92% [5.3A]

13

23

2. 0.04 [5.1B] 3. 0.005 [5.1B] 4. 45% [5.1C] 5. 70% [5.1C] 6. 135% [5.1C] 7.  [5.1A] 8. 1 [5.1A] 20 50 10. 35% [5.1E] 11. 37.5% [5.1E] 12. 175% [5.1E] 13. 45 [5.2A] 14. 45% [5.2A] 15. 80 [5.2A] 17. $960 [5.4B] 18. $40; 16% off [5.5C] 19. $220.50 [5.4A] 20. $100 [5.6A] 21. $2,520 [5.6B]

A Glimpse of Algebra 1. 9

3. 180

8 15

7. 

5. 8

9. 20

17 13

22 23

4 13

13.   1

11. 36

15. 

17. 140

19. 25

21. 3

23. 1

25. 21

Chapter 6 Getting Ready for Chapter 6 2 5

1.  12. 0.4

4 1

2. 

3. 192

13. 50

4. 12,500

14. 3.65

5. 3,267,000

15. 750

6. 3,600

16. 24

17. 122

7. 9.3375 18. 38.9

2 3

9. 2

8. 190.4

19. 0.75

10. 0.025

11. 450

20. Perimeter  120 in., Area  864 in2

Section 6.1 1

1

1. 60 in. 3. 120 in. 5. 6 ft 7. 162 in. 9. 2 ft 11. 13,200 ft 13. 1 yd 15. 1,800 cm 17. 4,800 m 19. 50 cm 4 3 21. 0.248 km 23. 670 mm 25. 34.98 m 27. 6.34 dm 29. 5.3 miles 31. 20 yd 33. 80 in. 35. 244 cm 37. 2,960 chains 39. 120,000 ␮m 41. 7,920 ft 43. 80.7 ft/sec 45. 19.5 mi/hr 47. 1,023 mi/hr 49. 3,965,280 ft 51. 179,352 in. 53. 2.7 mi 55. 18,094,560 ft 57. 144 59. 8 61. 1,000 63. 3,267,000 65. 6 67. 0.4 69. 405 1 1 7 71. 450 73. 45 75. 2,200 77. 607.5 79.  81. 6 83. 3 85. 6 87. 6 89.  2.5 ft 1 step

3

1 mi 5,280 ft

2

10

91. 10,000 steps      4.7 mi

Section 6.2 1. 432 in2 3. 2 ft2 5. 1,306,800 ft2 7. 1,280 acres 9. 3 mi2 11. 108 ft2 13. 1,700 mm2 15. 28,000 cm2 2 2 2 17. 0.0012 m 19. 500 m 21. 700 a 23. 3.42 ha 25. 135 ft 27. 48 fl oz 29. 8 qt 31. 20 pt 33. 480 fl oz 35. 8 gal 37. 6 qt 39. 9 yd3 41. 5,000 mL 43. 0.127 L 45. 4,000,000 mL 47. 14,920 L 49. 2,177,280 acres 51. 30 a 53. 5,500 bricks 55. 16 cups 57. 34,560 in3 59. 48 glasses 61. 20,288,000 acres 63. 3,230.93 mi2 17 5 1 3 65. 23.35 gal 67. 21,492 ft 69. 192 71. 6,000 73. 300,000 75. 12.5 77.  79. 9 81.  83.  8

3

144

Section 6.3 1. 128 oz 3. 4,000 lb 5. 12 lb 7. 0.9 T 9. 32,000 oz 11. 56 oz 13. 13,000 lb 15. 2,000 g 17. 40 mg 19. 200,000 cg 21. 508 cg 23. 4.5 g 25. 47.895 cg 27. 1.578 g 29. 0.42 kg 31. 48 g 33. 4 g 35. 9.72 g 37. 120 g 51. 50

39. 3 L 53. 50

75. 3.625

77.

41. 1.5 L 55. 122

1  8

79.

1 6 4

43. 0.561 grams

57. 248 81. 0.125

59. 40

45. a. 3 capsules b. 1 capsule c. 2 capsules 9 50

61. 

9 100

63. 

4 5

65. 

3 4

67. 1

69. 0.75

47. 20.32 71. 0.85

49. 6.36 73. 0.6

83. 6.25

Section 6.4 1. 15.24 cm 3. 13.12 ft 5. 6.56 yd 7. 32,200 m 9. 5.98 yd2 11. 24.7 acres 13. 8,195 mL 15. 2.12 qt 17. 75.8 L 19. 339.6 g 21. 33 lb 23. 365°F 25. 30°C 27. 58°C 29. 7.5 mL 31. 3.94 in. 33. 7.62 m 35. 46.23 L 37. 17.67 oz 39. Answers will vary. 41. 91.46 m 43. 20.90 m2 45. 88.55 km/hr 47. 2.03 m 49. 38.3°C 51. 75 53. 82 55. 3.25 57. 22 59. 41 61. 48 63. 195 65. 3.25 67. $90 69. mean  8, range  6 71. mean  6, range  9 73. median  21, range  14 75. median  40, range  16 77. mode  14, range  7 79. a. 73 b. 71 c. 70 d. 23 81. 381.8 mg/day; 1.52 mL/day

A-13

Answers to Odd-Numbered Problems

Section 6.5 1. a. 270 min b. 4.5 hr 3. a. 320 min b. 5.33 hr 5. a. 390 sec b. 6.5 min 7. a. 320 sec b. 5.33 min 9. a. 40 oz b. 2.5 lb 11. a. 76 oz b. 4.75 lb 13. a. 54 in. b. 4.5 ft 15. a. 69 in. b. 5.75 ft 17. a. 9 qt b. 2.25 gal 19. 11 hr 21. 22 ft 4 in. 23. 11 lb 25. 5 hr 40 min 27. 3 hr 47 min 29. 52 min 31. 7.5 seconds 33. 8:18:18; 9:08:01 35. 00:06:15 37. $104 39. 10 hr 41. $150 43. $6 45. 47. 1.79 sec CAFFEINE CONTENT IN SOFT DRINKS Drink

Caffeine (In Milligrams)

Jolt Mountain Dew Coca-Cola Diet Pepsi 7 up

100 55 45 36 0

Chapter 6 Review 1. 144 in. 3. 0.49 in. 5. 435,600 ft2 7. 576 in2 9. 6 gal 11. 128 oz 19. 141.5 g 21. 248°F 23. 8.52 liters 25. 4,383.23 mi2 27. 402.5 km 35. 322 km/hr 37. 13 lb

13. 5,000 g 15. 10.16 cm 17. 7.42 qt 29. 600 bricks 31. 80 glasses 33. 117 mi/hr

Chapter 6 Cumulative Review 1. 16,759 25. 11.5

5. 4901

3. 12

7. 21

32

27. 72 in., 207 in2

29. 47

9. 38 31. 1,788

11. 13

13. 11.07

15. 16.2

2 5

19. 6

17. 153

4 5

23. 14

21. 0.75

33. 42

Chapter 6 Test 1. 21 ft [6.1A] 2. 0.75 km [6.1B] 3. 130,680 ft2 [6.2A] 4. 3 ft2 [6.2A] 5. 10,000 mL [6.2D] 6. 8.05 km [6.2B] 7. 10.6 qt [6.4A] 8. 26.7° C [6.4B] 9. 0.26 gal [6.4A] 10. 20,844 in. [6.1A] 11. 0.24 ft3 [6.2A] 12. 70.75 liters [6.4A] 13. 74.70 m [6.4A] 14. 7.55 liters [6.4A] 15. 90 tiles [6.5C] 16. 64 glasses [6.5C] 17. a. 330 min b. 5.5 hr [6.4A] 18. 11 lb [6.5A]

Chapter 7 Getting Ready for Chapter 7 1. (5  3)2 2. 4(7  2) 14. 8 15. 3 16. 4

3. 110.1 17. 24 in.

4. 9 5. 0.32 18. 7,500 ft2

6. 0

7. 125

9 10

8. 

9. 6

10. 2

11. 3

12. 1

5 16

13. 

Problem Set 7.1 3. 5 is greater than 2.

1. 4 is less than 7. 13. 3 15

15. 3  7

17. 7 5

3  6

19. 6  0

21. 12  2

31. 15 4 33. 2  7 35. 2 37. 100 7 3 53. 2 55. 75 57. 0 59. 0.123 61.  63. 2 8 100 77. 20 79. 360 81. 450 feet 83. 3,060 feet New Orleans 6:00 GMT 93. 7 F 95. 10 F and 25-mph wind 99. 25 101. 5 103. 6 40°

Temperature (Fahrenheit)

29. 51. 75. 91. 97.

5. 10 is less than 3.

7. 0 is greater than 4. 23.

3 1    2 4 41. 231

25. 0.75  0.25

39. 8 43. 65. 8 67. 2 69. 85. $5,000; $2,750 105. 19

9. 30 30

107. 4,313

3  4 8

47. 8 49. 231 73. Positive 87. 61 F, 51 F 89. 5 F, 15 F

109. 56

20° 10° 0° 1

2

3

4

5

6

7

8

27. 0.1  0.01

45. 200 71. 0

30°

−10°

11. 10  0

9 10 11 12

−20° −30° −40°

Months

113. (7  2) 6 115. x  4 117. y  5 119. 3 121. The opposite of a number is the number that is the same distance from 0, but on the opposite side of 0. 123. The opposite of the absolute value of 3. It simplifies to 3.

111. 5  3

A-14

Answers to Odd-Numbered Problems

Problem Set 7.2 1. 5 3. 1 5. 2 29. 127 31. 49

7. 6 33. 34

9. 4 35.

13. 9

11. 4

15. 15

17. 3

First Number a

Second Number b

Their Sum ab

5 5 5 5 5

3 4 5 6 7

2 1 0 1 2

19. 11 37.

39. 10 41. 445 43. 107 45. 20 47. 17 49. 50 51. 7 53. 3 2 3 63. 3.8 65. 14.4 67. 9.89 69. 1 71.  73.  75. 0.86 7

85. 4

87. 7

105. 2

107. 3

89. 10 109. 604

113. 10  x

111. 0

95. 2

93. $10

23. 3

25. 16

27. 8

First Number x

Second Number y

Their Sum xy

5 5 5 5 5

3 4 5 6 7

8 9 10 11 12

55. 50 57. 73 59. 11 61. 17 1 77. 4.2 79.  81. 21 83. 5

5

91. 380 feet above the trailhead

21. 7

2 5

4

97. 4

99. 

101. 30

19. 13

21. 50

23. 100

103. 60.3

115. y  17

Problem Set 7.3 1. 2

5. 8

3. 2

27. 21

7. 5

29. 11.41

9. 7

31. 1.9

11. 12

15. 7

13. 3 35. 

9. 9.03 b. 16

11. 

17. 3 11 15

5 12

33. 1

1. 56 3. 60 5. 56 7. 81 23. a. 125 b. 125 25. a. 16 27. 29. Number x

Square x2

3 2 1 0 1 2 3

9 4 1 0 1 4 9

Second Number y

6 6 6 6 6

2 1 0 1 2

33. 50 35. 1 37. 35 39. 22 57. 4 59. 17 61. a 63. d

77. 5

79. 5

97. 54, 162

83. 4

99. 54, 162

13. 8

First Number x

31. 4 55. 6

81. 9

3 7

85. 17

101. 44

39. 7

15. 24

41. 9

43. 14

25. 399

47. 11 1 49. 202 51. 400 53. 17.5 55.  57. 11 59. 4 61. 8 63. 6 65. b 67. a 69. 100 12 71. 16 degrees 73. 7,603 feet 75. 100 items 77. $1,760 79. $3,009 81. 11  (22)  11° F 83. 3  (24)  27° F 85. 60  (26)  86° F 87. 14  (26)  12° F 89. 30 91. 36 93. 64 95. 48 97. 41 99. 40 101. 17 103. 32 105. 25 107. 72 109. 3  5 111. 7x 113. 5(3) 115. (5  7)  8 117. 2(3)  2(4)  6  8  14 119. 3  5  5  3 121. You have a balance of $10 in your checkbook, and you write a check for $12. Your new balance is $2. 123. 5, 10 125. 2, 6

Problem Set 7.4

37. 

19. 6

17. 24

45. 65

21. a. 16 b. 16

Their Product xy 12 6 0 6 12

41. 30 43. 25 45. 9 47. 13 49. 11 51. 19 53. 6 65. a 67. b 69. 6°C 71. 16 degrees 73. $400 remains 75. 7 12 6

89. 12  6 or 

87. 405 103. 19

91. 6  3  2

93. 5  2  10

95. 89

105. 17

Problem Set 7.5 1. 3 17.

3. 5

5. 3

7. 2

First Number

Second Number

a

b

100 100 100 100

5 10 25 50

21. 5 47. 5

9. 4

11. 2

13. 0

The Quotient of a and b a  b

15. 5 19.

Second Number

a

b

100 100 100 100

20 10 4 2

23. 35 25. 6 27. 1 29. 6 31. 2 49. 20 51. 5 53. 1 55. c 57. a

First Number

33. 1 59. d

35. 1 37. 2 61. $9,810.50

The Quotient of a and b a  b

5 5 5 5

39. 3

20 20 20 20

41. 7

43. 30

45. 4

A-15

Answers to Odd-Numbered Problems 63.

65. x  3



67. (5  7)  a

69. (3  4)y

71. 5(3)  5(7)

73. 36

75. 64

77. 350

6° 4°

Sun

Sat

Fri

Thu

Wed

0° −2°

Tue

2° Mon

Temperature (Fahrenheit)

10°

−4° −6° −8° −10°

79. 7,500

83. 12

81. 4

85. 12

87. 32

91. 2

89. 32

93. 4

95. 4

97. 1

99. 1

Problem Set 7.6 1. 20a 3. 48a 5. 18x 7. 27x 9. 10y 11. 60y 13. 5  x 15. 13  x 17. 10  y 19. 8  y 21. 5x  6 23. 6y  7 25. 12a  21 27. 7x  28 29. 7x  35 31. 6a  42 33. 2x  2y 35. 20  4x 37. 6x  15 39. 18a  6 41. 12x  6y 43. 35  20y 45. 8x 47. 4a 49. 4x 51. 5y 53. 10a 55. 5x 57. x($3,300  $300)  $250  $3,000x  $250 59. A  36 ft2; P  24 ft 61. A  81 in2; P  36 in. 63. A  200 in2; P  60 in. 65. A  300 ft2; P  74 ft 67. 20° C 69. 5° C 71. 10° C

Chapter 7 Review 1. 17 3. 4.6 5. 6 7. 2 9. 4 11. 6 13. 2 15. 971 17. 12 19. 7 21. 20 23. 1,736 25. 3 27. 2 29. 36 31. 8 33. 5 35. 8 37. 1 39. 4 41. 42 43. 11 45. 27 47. 2 49. False 51. True 53. False 55. $58  ($86)  $28 57. 24° 59. 3x  12 61. 21a 63. 4x  12 65. 21y  56 67. 3x 69. 4y

Chapter 7 Cumulative Review 1 1. 3 35

6 5. 1

3. 316

21. 4.875

19 25

81

23. 

9 9. 3

7. 1

25. 40%

13. 6

11. Distributive property of multiplication

8

16

27. 53.06 L

29. 20

31. 17°

33. 20 women

15. 0.098

7

35. 97 mi.

37. $10.80

17. 6

19. 8 9

39. 20 baskets

Chapter 7 Test 1. 14 [7.1C] 8. 5.9 [7.3A]

Garbage (millions of tons)

16. 8 [7.5B] 24. 5 [7.5A]

2 3. 1 4 [7.1A] 3 22 9.  [7.2B] 10. 36 [7.3A] 15 17. 11 [7.5B] 18. 15 [7.5B] 250 25. [7.1D]

2.  [7.1C]

11. 42 [7.4A] 19. 7 [7.5B]

5. 7 [7.1C]

12. 6 [7.4A] 20. 4 [7.5B] 26. $35 [7.2C]

6. 2 [7.1B]

7. 9 [7.2B]

13. 5 [7.5A]

14. 5 [7.5A]

21. 61 [7.2B] 27. 25° [7.3B]

22. 7 [7.3A] 23. 24 [7.4A] 28. 7x  35 [7.6B]

15. 9 [7.5B]

200 150 100 50

0

29. 20x  4 [7.6B]

4. 4 2 [7.1A]

1960

30. 18x  16y [7.6B]

1970

1980

1990

2000

31. 32x [7.6C]

32. 8a [7.6C]

Chapter 8 Getting Ready for Chapter 8 11

1. 5 2. 135 3. 6 4.  8 15. 4x  20 16. x 17. x  2

5. 20 6. 2 18. P  8x

7. 18

8. 1

2 3

9. 

10. 13

11. 7

12. 35

13. 10x

14. 12x

Problem Set 8.1 1. 10x 3. y 5. 3a 7. 8x  16 9. 6a  14 11. x  2 13. 6x  11 15. 2x  2 17. a  12 19. 4y  4 21. 2x  4 23. 8x  6 25. 5a  9 27. x  3 29. 17y  3 31. a  3 33. 6x  16 35. 10x  11 37. 19y  32 39. 30y  18 41. 6x  14 43. 27a  5 45. 14 47. 27 49. 19 51. 7 53. 1 55. 18 57. 12 59. 10 61. 28 63. 40 65. 26 67. 4 69. 3 71. 0 73. 15 75. 6 77. 6(x  4)  6x  24 79. 4x  4 81. 10x  4 83. 5° 85. 55°; complementary angles 87. 20°; complementary angles 89. a. Yes b. No, he should earn $108 for working 9 hours c. No, he should earn $84 for working 7 hours d. Yes 91. a. 32°F b. 22°F c. 18°F 109. 9 111. 6

113. a

93. a. $27 b. $47 115. c

117. c

119.

95. 0 2  3

97. 6 121. 18

99. 3 123.

1  12

11 8

101. 

103. 0

105. x

107. y  2

A-16

Answers to Odd-Numbered Problems

Problem Set 8.2 1. Yes 29. 3 53. 67° 77.

5. No 7. Yes 9. No 11. 6 13. 11 15. 15 33. 6 35. 6 37. 1 39. 2 41. 16

3. Yes 31. 2

5  14

1  15

79.

81.

1 3 59. 2 61.  63. 1 4 2 Equation: x  12  30; x  18

57. 

55. a. 225 b. $11,125 7  6

83.

Problem Set 8.3

17. 1 19. 3 43. 3 45. 10 65. 1

67. 1

7

21. 1 23.  25. 10 27. 4 5 47. x  4 49. x  12 51. 58° celsius 69. 1

73. 7x  11

71. x

75. 2

85. Equation: 8  5  x  7; x  4

3

1. 8 3. 6 5. 6 7. 6 9. 16 11. 16 13.  15. 7 17. 8 19. 6 21. 2 23. 3 25. 4 27. 24 2 1 29. 12 31. 8 33. 15 35. 3 37. 1 39. 1 41. 3 43. 1 45. 1 47.  49. 14 51. 9 53. 8 3

55. 308 ft/s 65. 6a  16

61. 2x  5  19; x  7

57. $35.00 59. 97,500,000 or 97.5 million viewers 67. 15x  3 69. 3y  9 71. 16x  6

3 5

63. 5x  6  9; x  

Problem Set 8.4 1. 3 3. 2 5. 3 7. 4 9. 1 11. 0 13. 2 15. 2 17. 3 19. 1 21. 7 23. 3 1 31. 10 33. 5 35.  37. 3 39. 20 41. 1 43. 5 45. 4 47. 2.05 49. 0.064 12 55. 0.175 57. 2 59. 10 61. 5 63. 1,250 feet 65. 13 67. 30 hours 69. x  2 71. 2x 77. 2x  5 79.  81. 83. 0.001, 0.003, 0.01, 0.013, 0.03, 0.031 85. a. 4x  6(x  100)  2,400 b.

25. 1 27. 2 29. 4 51. 12.03 53. 0.44 73. 2(x  6) 75. x  4 x  300 c. 500 people

Problem Set 8.5 1. x  3 3. 2x  1 5. 5x  6 7. 3(x  1) 9. 5(3x  4) 11. The number is 2. 13. The number is 2. 15. The number is 3. 17. The number is 5. 19. The number is 2. 21. The length is 10 m and the width is 5 m. 23. The length of one side is 8 cm. 25. The measures of the angles are 45°, 45°, and 90°. 27. The angles are 30°, 60°, and 90°. 29. Patrick is 33 years old, and Pat is 53 years old. 31. Sue is 35 years old, and Dale is 39 years old. 33. 87 mi 35. 147 mi 37. 8 nickels, 18 dimes 39. 16 dimes, 32 quarters 41. x  8, y  6, z  9 43. 39 hours 45. 60 miles per hour 47. 35 49. 65

51. 2

53. 14

2 3

55. 

57. 0.75, 75%

59. 1.2, 120%

37 100

61. , 0.37

17 500

63. , 0.034

65. 20.25

67. 75

Problem Set 8.6 9

1. 704 ft2 3.  in2 5. $240 7. $285 9. 12 ft 8 21. C  20°C; yes 23. 0°C 25. 5°C 27. 29.

13. $140

AGE (YEARS)

MAXIMUM HEART RATE (BEATS PER MINUTE)

RESTING HEART RATE

TRAINING HEART RATE

18

202

60

144

19

201

65

146

20

200

70

148

21

199

75

150

22

198

80

152

23

197

85

154

1 4

13 4

17. 3   ft

15. 58 in.

19. C  100°C; yes

31. a. 4 hrs b. 220 miles

37. 1 yd3 39. y  7 41. y  3 43. y  2 45. x  3 47. x  5 49. x  8 5 13 13 y1 53. y  3 55. y   57. y  0 59. y   61. y  4 63. x  0 65. x   67. x  3 2 3 4 Complement: 45°; supplement: 135° 71. Complement: 59°; supplement: 149° 73. a. 13,330 kilobytes b. 2,962 kilobytes 3 a. About 58° Celcius b. 328 K 77.  79. 3 81. 2 83. 6 4

33. a. 4 hours b. 65 mph 51. 69. 75.

11. 8 ft

35. 360 in3

Chapter 8 Review 1. 17x 27. 2

3. 11a  3 5. 5x  4 7. 10a  4 9. 42 11. 1 29. 4 31. The length is 14 m, and the width is 7 m.

13. Yes 33. y  6

15. 9 17. 3 19. 9 35. y  3 37. x  0

1 8

21. 5 23. 1 39. x  2

25. 

Chapter 8 Cumulative Review 1. 5,996 23. 56

3. 4.559 25. 5

27. 8

5. 938,135

7. 42

29. 82 in

2

9. 440,000

31. 16 mpg

11. 61

33. 13 m

3

13. 80% 35. $21

15. 16

37. $45

25

17. 4 39.

81 240

19. 7

21. 4

12. 1

13. 2

Chapter 8 Test 1. 6x  5 2. 3b  4 3. 3 14. 1 15. 8 16. 22 mi/hr

4. 9 5. Yes 6. 8 7. 4 8. 4.9 9. 27 10. 6 11. 4 17. Length  9 cm; width  5 cm 18. Susan is 11, Karen is 6.

3

Index A Absolute value, 460 Acute angle, 524 Addition associative property of, 17 with carrying, 15 commutative property of, 16 with decimals, 214 with fractions, 148 with mixed numbers, 171 with negative numbers, 469,471 with table, 14 with whole numbers, 14 with zero, 16 Addition property of equality, 534 of zero, 16 Additive inverse, 461 Algebraic expression, 504, 521 value of, 523 Angle, 524 acute, 524 complementary, 524, 571 complement of, 524, 571 measure, 524 notation, 524 obtuse, 524 right, 524 sides of, 524 straight, 524 sum of (triangle), 560 supplementary, 524, 571 supplement of, 524, 571 vertex of, 524 Area, 81 of a circle, 227 metric units of, 419 of a parallelogram, 81 of a rectangle, 81, 417,506 of a square, 81, 417, 506 of a triangle, 131, 417 U.S. units of, 408 Arithmetic mean, 71 Associative property of addition, 17 of multiplication, 47 Average, 71, 73 Average speed, 571

B Bar chart, 28 Base, 67 Blueprint for problem solving, 557 Borrowing, 35, 174

C Carrying, 15 Celsius scale, 435

Circle, 225 area, 227 circumference, 225 diameter, 225 radius, 225 Circumference, 225 Commission, 360 Commutative property of addition, 16 of multiplication, 46 Complementary angles, 524, 571 Complex fractions, 180 Composite numbers, 119 Compound interest, 376 Conversion factors, 408 area, 418, 419 between metric and U.S. systems, 433 length, 409, 411 time, 441 volume, 420, 421 weight, 427 Counting numbers, 8 Cube, 84 Cylinder, 227

D Decimal fractions, 206 Decimal notation, 205 Decimal numbers, 206 addition with, 214 converting fractions to, 245 converting to fractions, 207, 246 converting to mixed numbers, 207 converting percents to, 334 converting to percents, 335 division with, 235 and equations, 552 expanded form, 206 multiplication with, 222 repeating, 246 rounding, 207 subtraction with, 214 writing in words, 206 Decimal point, 206 Degree measure, 524 Denominator, 107 least common, 149 Diameter, 225 Difference, 33 Digit, 3 Discount, 368 Distributive property, 43, 505, 521 Dividend, 55 Division with decimals, 235 with fractions, 139

long, 57 with mixed numbers, 166 with negative numbers, 497 with remainders, 59 with whole numbers, 56 by zero, 61 Divisor, 55, 119

E Equations applications of, 555 in one variable, 18, 47, 293, 541, 549 involving decimals, 552 involving fractions, 551 Equivalent fractions, 109 Estimating, 27, 44, 60, 223 Evaluating formulas, 569 Expanded form, 4, 206 Exponents, 67, 101 zero, 68 Extremes, 297

F Factor, 42, 119 Factoring into prime numbers, 119 Fahrenheit scale, 435 Formula, 569 Fraction bar, 55 Fractions, 107 addition with, 148 combinations of operations, 179 complex, 180 converting decimals to, 207, 246 converting to decimals, 245 converting percents to, 336 converting to percents, 337 denominator of, 107 division with, 139 and equations, 529 equivalent, 109 improper, 108 least common denominator, 149 lowest terms, 120 meaning of, 107 multiplications with, 127 and the number one, 111 numerator of, 108 proper, 108 properties of, 110 as ratios, 279 reducing to lowest terms, 120, 129 subtraction with, 148 terms of, 107 Fundamental property of proportions, 298

G Geometric sequence, 54 Grade point average, 238 Greater than, 460

H Hypotenuse, 259

I Improper fractions, 108 Inequality symbols, 460 Integers, 461 Interest compound, 376 principal, 375 rate, 375 simple, 375 Irrational number, 225, 259

K Kronecker, Leopold, 100

L Least common denominator, 149, 551 Length metric units of, 410 U.S. units of, 408 Less than, 460 Line graph, 462 Linear equations in one variable, 549 Long division, 57 Lowest terms, 120

M Mean, 71 Means, 297 Median, 72 Metric system converting to U.S. system, 433 prefixes of, 409 units of, 410, 419, 421, 427 Mixed numbers, 159 addition with, 171 borrowing, 174 converting decimals to, 246 converting improper fractions to, 161 converting to improper fractions, 159 division with, 166 multiplication with, 165 notation, 159 subtraction with, 173 Mode, 72

I-1

I-2

Index

Multiplication associative property of, 47 commutative property of, 46 with decimals, 222 with fractions, 127 with mixed numbers, 165 with negative numbers, 489 by one, 46 with whole numbers, 43, 46 by zero, 46 Multiplication property of equality, 541 of one, 46 of zero, 46

N Negative numbers, 459 addition with, 469, 471 division with, 497 multiplication with, 489 subtraction with, 479 Number line, 8, 459 Numbers absolute value of, 460 composite, 119 counting, 8 decimal, 205 integer, 461 irrational, 225, 259 mixed, 159 negative, 459 opposite of, 461 positive, 459 prime, 119 rounding, 25, 207 whole, 8 writing in words, 6 writing with digits, 7 Numerator, 108

O Obtuse angle, 524 Opposite, 461 Order of operations, 69 Origin, 459

P Parallelogram area of, 81 Pascal’s triangle, 3

Percents applications, 353 basic percent problems, 343 and commission, 360 converting decimals to, 335 converting fractions to, 337 converting to decimals, 334 converting to fractions, 336 and discount, 367 increase and decrease, 367 meaning of, 333 and proportions, 346 and sales tax, 359 Perfect square, 258 Perimeter, 19 of a square, 19, 506 of a rectangle, 19, 506 Pi, 225 Pie chart, 107, 383 Place value, 3, 205 Polygon, 19 Positive numbers, 459 Prime numbers, 119 Product, 42 Proper fractions, 108 Proportions, 297 applications of, 303, 346 extremes, 297 fundamental property of, 298 means, 297 terms of, 297 Protractor, 385, 525 Pythagorean theorem, 259

Q Quotient, 55

R Radical sign, 257 Radius, 225 Range, 74 Rate equation, 570 Rates, 287 Ratio, 279 Reciprocal, 139 Rectangle, 19 area, 81, 417, 506 perimeter, 19, 506 Rectangular solid surface area, 85

volume, 84 Remainder, 59 Right angle, 524 Right circular cylinder, 227 Right triangle, 259 Rounding decimals, 207 whole numbers, 25

S Sales tax, 359 Scatter diagram, 462 Sequence geometric, 54 Set, 8 Similar figures, 309 Simple interest, 375 Similar terms, 505, 521 Solution, 18, 533, 549 Sphere, 249 Square, 19 area, 81, 417, 506 perimeter, 19, 506 Square root, 257 approximating, 258 simplifying, 258 Straight angle, 524 Study skills, 5, 7, 8, 17, 74, 86, 107, 111, 132, 181, 216, 228, 238, 279, 300 Subraction with borrowing, 35, 174 with decimals, 214 with fractions, 148 with mixed numbers, 171 with negative numbers, 479 with whole numbers, 34 Supplementary angles, 524, 571 Sum, 15 Surface area, 85

T Temperature, 433 Terms of a fraction, 108 of a proportion, 297 similar, 505, 521 Time, 441 Triangle, 19 area, 131, 417

labeling, 560 perimeter, 19 right, 259 similar, 309 sum of angles in, 560

U Unit analysis, 407, 417, 427 Unit pricing, 288 Units area, 418, 419 length, 408, 410 mixed, 441 volume, 420, 421 weight, 427

V Variable, 505 Vertex of an angle, 524 Volume, 84 metric units of, 421 rectangular solid, 84 right circular cylinder, 227 sphere, 249 U.S. units of, 420

W Weight metric units of, 427 U.S. units of, 427 Weighted average, 237 Whole numbers, 8 addition with, 15 division with, 56 multiplication with, 43, 46 rounding, 25 subtraction with, 34 writing in words, 6 Writing numbers in words, 6, 206 with digits, 7

Z Zero and addition, 16 and division, 61 as an exponent, 68 and multiplication, 46